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.     

Functional Diversity and Evolution of Bitter Taste Receptors in Egg-Laying Mammals

Egg-laying mammals (monotremes) are a sister clade of therians (placental mammals and marsupials) and a key clade to understand mammalian evolution. They are classified into platypus and echidna, which exhibit distinct ecological features such as habitats and diet. Chemosensory genes, which encode sensory receptors for taste and smell, are believed to adapt to the individual habitats and diet of each mammal. In this study, we focused on the molecular evolution of bitter taste receptors (TAS2Rs) in monotremes. The sense of bitter taste is important to detect potentially harmful substances. We comprehensively surveyed agonists of all TAS2Rs in platypus (Ornithorhynchus anatinus) and short-beaked echidna (Tachyglossus aculeatus) and compared their functions with orthologous TAS2Rs of marsupial and placental mammals (i.e., therians). As results, the agonist screening revealed that the deorphanized monotreme receptors were functionally diversified. Platypus TAS2Rs had broader receptive ranges of agonists than those of echidna TAS2Rs. While platypus consumes a variety of aquatic invertebrates, echidna mainly consumes subterranean social insects (ants and termites) as well as other invertebrates. This result indicates that receptive ranges of TAS2Rs could be associated with feeding habits in monotremes. Furthermore, some orthologous receptors in monotremes and therians responded to β-glucosides, which are feeding deterrents in plants and insects. These results suggest that the ability to detect β-glucosides and other substances might be shared and ancestral among mammals.     

苦味受体与甜味、鲜味受体具有不同的进化途径

通过生物信息学和系统发育学分析,研究了苦味受体和甜味／鲜味受体的进化途径。结果显示,苦味受体和甜味／鲜味受体在进化上具有远相关,并且具有不同的进化途径,提示这可能是导致这些受体具有不同功能,传导不同味觉的原因。     

Functional Analyses of Bitter Taste Receptors in Domestic Cats (Felis catus)

Cats are obligate carnivores and under most circumstances eat only animal products. Owing to the pseudogenization of one of two subunits of the sweet receptor gene, they are indifferent to sweeteners, presumably having no need to detect plant-based sugars in their diet. Following this reasoning and a recent report of a positive correlation between the proportion of dietary plants and the number of Tas2r (bitter receptor) genes in vertebrate species, we tested the hypothesis that if bitter perception exists primarily to protect animals from poisonous plant compounds, the genome of the domestic cat (Felis catus) should have lost functional bitter receptors and they should also have reduced bitter receptor function. To test functionality of cat bitter receptors, we expressed cat Tas2R receptors in cell-based assays. We found that they have at least 7 functional receptors with distinct receptive ranges, showing many similarities, along with some differences, with human bitter receptors. To provide a comparative perspective, we compared the cat repertoire of intact receptors with those of a restricted number of members of the order Carnivora, with a range of dietary habits as reported in the literature. The numbers of functional bitter receptors in the terrestrial Carnivora we examined, including omnivorous and herbivorous species, were roughly comparable to that of cats thereby providing no strong support for the hypothesis that a strict meat diet influences bitter receptor number or function. Maintenance of bitter receptor function in terrestrial obligate carnivores may be due to the presence of bitter compounds in vertebrate and invertebrate prey, to the necessary role these receptors play in non-oral perception, or to other unknown factors. We also found that the two aquatic Carnivora species examined had fewer intact bitter receptors. Further comparative studies of factors driving numbers and functions of bitter taste receptors will aid in understanding the forces shaping their repertoire.     

Human Bitter Taste Receptors hTAS2R8 and hTAS2R39 with Differential Functions to Recognize Bitter Peptides

The strong bitter peptide, Phe-Phe-Pro-Arg, activated cultured cells expressing either of the known human bitter taste receptors, hTAS2R8 and hTAS2R39. The partial structure of Pro-Arg activated hTAS2R39, but did not activate hTAS2R8. These receptors may not indiscriminately recognize bitter peptides, but have a differential function in their recognition.     

黄芩苷通过苦味受体促进哮喘小鼠呼吸道炎性细胞凋亡

全球哮喘患者有3亿多人。目前,约有一半患者的病情不能较好地用现有药物来控制。因此,寻找新的更有效的治疗哮喘病的药物是非常必要的。最近的研究发现,苦味受体(bitter taste receptors,Tas2rs)在呼吸系统中表达,且苦味剂对哮喘有治疗潜力,苦味受体可能成为哮喘治疗的新靶点。为此,本文研究了苦味化合物黄芩苷(baicalin,BA)对哮喘的干预作用,分析黄芩苷对哮喘小鼠呼吸道炎性细胞凋亡的干预作用及其与苦味信号转导的关系。选雄性BALB/c小鼠,随机分为对照组(CK组)、腹腔注射致敏加雾化吸入卵清蛋白(ovalbumin,OVA)激发制成的哮喘模型组(OVA组)和黄芩苷灌胃干预哮喘组(OVA+BA组)。结果发现,OVA组小鼠肺泡灌洗液中白细胞总数和分类细胞计数显著增加,黄芩苷干预组白细胞数量显著减少;HE染色后,OVA组小鼠肺组织中可见炎性细胞浸润、肺泡隔增厚和肺泡囊缩小,上述症状在OVA+BA组小鼠肺部明显减轻;实时荧光定量RT-PCR检测发现,肺组织中黏蛋白Muc5ac表达水平在OVA组明显增高(P <0.05),黄芩苷干预组显著低于OVA组(P <0.05)。OVA致敏哮喘小鼠呼吸道中Tas2r108、Tas2r126、Tas2r135和Tas2r143及其下游信号转导分子α-gust和Trpm5下调表达(P <0.05),促凋亡因子P53、Bax和胱天蛋白酶(caspase,Casp)Casp3转录抑制,凋亡抑制基因Bcl2上调表达,胱天蛋白酶3活性显著降低(P <0.05);黄芩苷干预组4个Tas2rs及苦味信号转导分子转录上调(P <0.05),促凋亡基因P53、Bax和Casp3转录上调,Bcl2转录抑制,胱天蛋白酶3活性显著高于OVA组(P <0.05)。结果表明,黄芩苷干预可激活哮喘鼠呼吸道苦味信号转导通路,并使呼吸道炎性细胞减少、黏蛋白分泌减少。即苦味物质黄芩苷可能作为一种苦味受体激动剂,通过激活苦味信号转导系统促进呼吸道炎性细胞凋亡,减轻肺部炎症和损伤,缓解哮喘发作。     

Age-Related Differences in Bitter Taste and Efficacy of Bitter Blockers

Background

Bitter taste is the primary culprit for rejection of pediatric liquid medications. We probed the underlying biology of bitter sensing and the efficacy of two known bitter blockers in children and adults.

Methods

A racially diverse group of 154 children (3-10 years old) and their mothers (N = 118) evaluated the effectiveness of two bitter blockers, sodium gluconate (NaG) and monosodium glutamate (MSG), for five food-grade bitter compounds (quinine, denatonium benzoate, caffeine, propylthiouracil (PROP), urea) using a forced-choice method of paired comparisons. The trial was registered at clinicaltrials.gov ({"type":"clinical-trial","attrs":{"text":"NCT01407939","term_id":"NCT01407939"}}NCT01407939).

Results

The blockers reduced bitterness in 7 of 10 bitter-blocker combinations for adults but only 3 of 10 for children, suggesting that efficacy depends on age and is also specific to each bitter-blocker combination. Only the bitterness of urea was reduced by both blockers in both age groups, whereas the bitterness of PROP was not reduced by either blocker in either age group regardless of TAS2R38 genotype. Children liked the salty taste of the blocker NaG more than did adults, but both groups liked the savory taste of MSG equally.

Conclusions and Relevance

Bitter blocking was less effective in children, and the efficacy of blocking was both age and compound specific. This knowledge will pave the way for evidence-based strategies to help develop better-tasting medicines and highlights the conclusion that adult panelists and genotyping alone may not always be appropriate in evaluating the taste of a drug geared for children.     

Bitter Taste of Oxidized Fatty Acids

A strong bitter taste was reported previously in highly autoxidized soybean oil, especially in the free fatty acid fraction. In the present study, for the elucidation of bitter substances in autoxidized oils, autoxidized linoleic acid was fractionated by silicic acid column chromatography, and the fraction with maximum peroxide value was treated with cysteine-ferric trichloride, reduced with sodium borohydride, oxidized with chromic acid and esterified with diazomethane. The results indicated that the bitter substances of autoxidized linoleic acid possessed a particular structure between the carboxyl group and other functional groups. To verify this fact, four oxidized fatty acids [ricinoleic(12-hydroxyoctadecenoic), 12-oxooctadecenoic, 9,12-dioxooctadecenoic, and dihydroxyoctadecenoic acids] were synthesized from castor oil, and their correlation to the bitter taste was investigated. The results showed that ricinoleic acid had a strong bitter taste, along with a strong stimulation, but this bitter taste was greatly reduced by methyl esterification. On the other hand, 12-hydroxy- and 9,10-dihydroxystearic acids were tasteless. From these results we conclude that the presence of an unsaturated bond, a carboxyl, a hydroxyl and/or peroxyl groups is a requisite for the bitterness of ricinoleic and autoxidized fatty acids.     

Bitter Taste Receptor Polymorphisms and Human Aging

Several studies have shown that genetic factors account for 25% of the variation in human life span. On the basis of published molecular, genetic and epidemiological data, we hypothesized that genetic polymorphisms of taste receptors, which modulate food preferences but are also expressed in a number of organs and regulate food absorption processing and metabolism, could modulate the aging process. Using a tagging approach, we investigated the possible associations between longevity and the common genetic variation at the three bitter taste receptor gene clusters on chromosomes 5, 7 and 12 in a population of 941 individuals ranging in age from 20 to 106 years from the South of Italy. We found that one polymorphism, rs978739, situated 212 bp upstream of the TAS2R16 gene, shows a statistically significant association (p = 0.001) with longevity. In particular, the frequency of A/A homozygotes increases gradually from 35% in subjects aged 20 to 70 up to 55% in centenarians. These data provide suggestive evidence on the possible correlation between human longevity and taste genetics.     

The Gustatory Signaling Pathway and Bitter Taste Receptors Affect the Development of Obesity and Adipocyte Metabolism in Mice

Intestinal chemosensory signaling pathways involving the gustatory G-protein, gustducin, and bitter taste receptors (TAS2R) have been implicated in gut hormone release. Alterations in gut hormone profiles may contribute to the success of bariatric surgery. This study investigated the involvement of the gustatory signaling pathway in the development of diet-induced obesity and the therapeutic potential of targeting TAS2Rs to induce body weight loss. α-gustducin-deficient (α-gust^-/-) mice became less obese than wild type (WT) mice when fed a high-fat diet (HFD). White adipose tissue (WAT) mass was lower in α-gust^-/- mice due to increased heat production as a result of increases in brown adipose tissue (BAT) thermogenic activity, involving increased protein expression of uncoupling protein 1. Intra-gastric treatment of obese WT and α-gust^-/- mice with the bitter agonists denatonium benzoate (DB) or quinine (Q) during 4 weeks resulted in an α-gustducin-dependent decrease in body weight gain associated with a decrease in food intake (DB), but not involving major changes in gut peptide release. Both WAT and 3T3-F442A pre-adipocytes express TAS2Rs. Treatment of pre-adipocytes with DB or Q decreased differentiation into mature adipocytes. In conclusion, interfering with the gustatory signaling pathway protects against the development of HFD-induced obesity presumably through promoting BAT activity. Intra-gastric bitter treatment inhibits weight gain, possibly by directly affecting adipocyte metabolism.     

Evaluation of the Suppressive Effect on Bitter Taste of Gluconate

Improved conditions for the production and characterization of 1-arylpropane-1, 2-diols and related compounds were developed. Experimental conditions providing highly enhanced activity of pyruvate decarboxylase in bakers’ yeast in the presence of pyruvate, thiamine pyrophosphate, and magnesium(II) salt were applied to the preparation of (R)-1-hydroxy-1-phenyl-2-propanone from benzaldehyde. Subsequent reduction with bakers’ yeast efficiently afforded 1-phenyl-1, 2-propanediol (35%). The composition of its stereoisomers was precisely determined, and the major (1R, 2S)-isomer (89% of the total mixture) could be isolated by recrystallizing the corresponding benzoate. The analytical method for identifying the stereoisomeric composition was also effective for the determination of 5-phenyl-4-pentene-2, 3-diol, the biotransformation product from cinnamaldehyde, the vinylogous substrate of benzaldehyde. Furthermore, the structural characterization of 1-(2-furyl)propane-1, 2-diol, which was obtained from furfural (28%) by the action of brewers’ yeast Saccharomyces cerevisiae (carlsbergensis), is described. The major (1S, 2S)-isomer could be isolated by recrystallizing the crude product.     

Signatures of Natural Selection in a Primate Bitter Taste Receptor

Bitter taste receptors (TAS2Rs) enable animals to detect and avoid toxins in the environment, including noxious defense compounds produced by plants. This suggests that TAS2Rs are under complex pressures from natural selection. To investigate these pressures, we examined signatures of selection in the primate TAS2R38 gene. Whole-gene (1,002 bp) sequences from 40 species representing all major primate taxa uncovered extensive variation. Nucleotide substitutions occurred at 448 positions, resulting in 201 amino acid changes. Two single-nucleotide deletions, one three-nucleotide in-frame deletion, and one premature stop codon were also observed. The rate of non-synonymous substitution (ω = dN/dS), was high in TAS2R38 (ω = 0.60) compared to other genes, but significantly lower than expected under neutrality (P = 4.0 × 10(-9)), indicating that purifying selection has maintained the basic structure of the receptor. However, differences were present among receptor subregions. Non-synonymous rates were significantly lower than expected in transmembrane domains (ω = 0.55, P = 1.18 × 10(-12)) and internal loops (ω = 0.51, P = 7.04 × 10(-5)), but not external loops (ω = 1.16, P = 0.53), and evidence of positive selection was found in external loop 2, which exhibited a high rate (ω = 2.53) consistent with rapid shifts in ligand targeting. These patterns point to a history of rapid yet constrained change in bitter taste responses in the course of primate evolution.     

A Novel Psychophysical Procedure for Bitter Taste Assessment in Rats

A persistent problem with attempts to examine bitter taste mechanismshas been the lack of adequate behavioral methodology providingdata which parallels that obtained from physiological investigations.We developed a brief contact procedure to assess the abilityof rats to detect the presence of a weak bitter compound dissolvedin a strong sucrose solution. Male Fischer 344 rats were trainedto drink immediately to multiple 10-s presentations of acetaminophen(2, 8, 32, 128 mM), chlorpheniramine maleate (1, 3, 9, 27 mM)L-tryptophan (13.5, 27, 54, 108 mM), pseudoephedrine hydrochloride(1, 4, 16, 64 mM) and quinine hydrochloride (0.008, 0.04, 0.2,1.0 mM) dissolved in 0.8 M sucrose. The number of licks to sucroseand water were also measured. A microcomputer controlled stimuluspresentations and measured the animal's licks of each solutionduring each 10-s presentation. The responses to the bitter +sucrose mixture were significantly decreased at most concentrationswith increasing levels of the bitter component. This was truefor all five bitter-tasting compounds, but over different concentrationranges relatively unique to each compound. The present studyis the first to characterize the sensory effects of acetaminophen,pseudoephedrine, and chlorpheniramine maleate, all purportedto taste bitter to humans. These results demonstrate rats' acuteability to discriminate by taste not only the presence but theconcentration of a dilute bitter compound dissolved in a strongsucrose solution. Chem. Senses 20: 305–312, 1995.     

Fetal Programming of Adult Glucose Homeostasis in Mice

Background

Emerging evidence suggests that dietary soy and phytoestrogens can have beneficial effects on lipid and glucose metabolism. We have previously shown that male mice fed from conception to adulthood with a high soy-containing diet had reduced body weight, adiposity and a decrease in glucose intolerance, an early marker of insulin resistance and diabetes.

Objectives

The purpose of this study was to identify the precise periods of exposure during which phytoestrogens and dietary soy improve lipid and glucose metabolism. Since intrauterine position (IUP) has been shown to alter sensitivity to endocrine disruptors, we also investigated whether the combination of IUP and fetal exposure to dietary phytoestrogens could potentially affect adult metabolic parameters.

Methods

Male outbred mice (CD-1) were allowed ad libitum access to either a high soy-containing diet or a soy-free diet either during gestation, lactation or after weaning. Adiposity and bone mass density was assessed by dual x-ray absorptiometry. Glucose tolerance was assessed by a glucose tolerance test. Blood pressure was examined by the tail-cuff system.

Results

Here we show that metabolic improvements are dependent on precise windows of exposure during life. The beneficial effects of dietary soy and phytoestrogens on adiposity were apparent only in animals fed post-natally, while the improvements in glucose tolerance are restricted to animals with fetal exposure to soy. Interestingly, we observed that IUP influenced adult glucose tolerance, but not adiposity. Similar IUP trends were observed for other estrogen-related metabolic parameters such as blood pressure and bone mass density.

Conclusion

Our results suggest that IUP and fetal exposure to estrogenic environmental disrupting compounds, such as dietary phytoestrogens, could alter metabolic and cardiovascular parameters in adult individuals independently of adipose gain.     

Peripheral Effects of Nesfatin-1 on Glucose Homeostasis

Aims/hypothesis

The actions of peripherally administered nesfatin-1 on glucose homeostasis remain controversial. The aim of this study was to characterize the mechanisms by which peripheral nesfatin-1 regulates glucose metabolism.

Methods

The effects of nesfatin-1 on glucose metabolism were examined in mice by continuous infusion of the peptide via osmotic pumps. Changes in AKT phosphorylation and Glut4 were investigated by Western blotting and immnuofluorescent staining. Primary myocytes, adipocytes and hepatocytes were isolated from male mice.

Results

Continuous peripheral infusion of nesfatin-1 altered glucose tolerance and insulin sensitivity in mice fed either normal or high fat diet, while central administration of nesfatin-1 demonstrated no effect. Nesfatin-1 increases insulin secretion in vivo, and in vitro in cultured min6 cells. In addition, nesfatin-1 up-regulates the phosphorylation of AKT in pancreas and min6 islet cells. In mice fed normal diet, peripheral nesfatin-1 significantly increased insulin-stimulated phosphorylation of AKT in skeletal muscle, adipose tissue and liver; similar effects were observed in skeletal muscle and adipose tissue in mice fed high fat diet. At basal conditions and after insulin stimulation, peripheral nesfatin-1 markedly increased GLUT4 membrane translocation in skeletal muscle and adipose tissue in mice fed either diet. In vitro studies showed that nesfatin-1 increased both basal and insulin-stimulated levels of AKT phosphorylation in cells derived from skeletal muscle, adipose tissue and liver.

Conclusions

Our studies demonstrate that nesfatin-1 alters glucose metabolism by mechanisms which increase insulin secretion and insulin sensitivity via altering AKT phosphorylation and GLUT 4 membrane translocation in the skeletal muscle, adipose tissue and liver.     

Suppression of Bitterness by Sodium: Variation Among Bitter Taste Stimuli

Taste interactions between salts (NaCl, LiCl, KCl, L-arginine:L-asparticacid, Na-acetate and Na-gluconate) and bittertasting compounds(urea, quinine HCI, magnesium sulphate, KCI, amiloride HCI andcaffeine) were investigated. In each study binary combinationsof three or four concentrations of one bitter compound withfour concentrations (0, 0.1, 0.3 and 0.5 M) of one salt wererated for bitterness and saltiness using the method of magnitudeestimation. In most cases, perceived bitterness was suppressedby salts, although the degree of suppression varied. In general,bitterness suppression was not accompanied by an equivalentreciprocal suppression of saltiness. Only MgSO₄ and amiloridehad suppressing effects on the saltiness of NaCl at the intermediateconcentrations and no bitter compound affected the saltinessat the high concentrations of NaCl. Since salt suppressed thebitterness of urea effectively, a detailed analysis of suppressionof the bitterness of urea by different salts was conducted.Those studies indicated that the key component in this effectwas the sodium or lithium ion for two reasons: first, all threesodium salts and the lithium salt had a suppressive effect onbitterness, whereas KCl did not; secondly, the effect of a salton suppression of the bitterness of urea was independent ofits perceived saltiness; that is, NaCl, Na-acetate (which isperceived as less salty than NaCl), and Na-gluconate (whichis perceived as less salty than Na-acetate) reduced bitternesscomparably. These results suggest that there is a major peripheralcomponent to the suppression of the bitterness of urea, andperhaps other bitter tasting compounds, by sodium. Chem. Senses20: 609–623, 1995.     

Receptor Polymorphism and Genomic Structure Interact to Shape Bitter Taste Perception

The ability to taste bitterness evolved to safeguard most animals, including humans, against potentially toxic substances, thereby leading to food rejection. Nonetheless, bitter perception is subject to individual variations due to the presence of genetic functional polymorphisms in bitter taste receptor (TAS2R) genes, such as the long-known association between genetic polymorphisms in TAS2R38 and bitter taste perception of phenylthiocarbamide. Yet, due to overlaps in specificities across receptors, such associations with a single TAS2R locus are uncommon. Therefore, to investigate more complex associations, we examined taste responses to six structurally diverse compounds (absinthin, amarogentin, cascarillin, grosheimin, quassin, and quinine) in a sample of the Caucasian population. By sequencing all bitter receptor loci, inferring long-range haplotypes, mapping their effects on phenotype variation, and characterizing functionally causal allelic variants, we deciphered at the molecular level how a subjects’ genotype for the whole-family of TAS2R genes shapes variation in bitter taste perception. Within each haplotype block implicated in phenotypic variation, we provided evidence for at least one locus harboring functional polymorphic alleles, e.g. one locus for sensitivity to amarogentin, one of the most bitter natural compounds known, and two loci for sensitivity to grosheimin, one of the bitter compounds of artichoke. Our analyses revealed also, besides simple associations, complex associations of bitterness sensitivity across TAS2R loci. Indeed, even if several putative loci harbored both high- and low-sensitivity alleles, phenotypic variation depended on linkage between these alleles. When sensitive alleles for bitter compounds were maintained in the same linkage phase, genetically driven perceptual differences were obvious, e.g. for grosheimin. On the contrary, when sensitive alleles were in opposite phase, only weak genotype-phenotype associations were seen, e.g. for absinthin, the bitter principle of the beverage absinth. These findings illustrate the extent to which genetic influences on taste are complex, yet arise from both receptor activation patterns and linkage structure among receptor genes.     

Positive Selection Drives the Evolution of Bat Bitter Taste Receptor Genes

Bitter taste reception is expected to be associated with dietary selection and to prevent animals from ingesting potentially harmful compounds. To investigate the genetic basis of bitter taste reception, we reconfirmed the bitter taste receptor (T2R) genes from cow (herbivore) and dog (carnivore) genome sequences and identified the T2R repertoire from the draft genome of the bat (insectivore) for the first time using an automatic data-mining method. We detected 28 bitter receptor genes from the bat genome, including 9 intact genes, 8 partial but putative functional genes, and 9 pseudogenes. In the phylogenetic analysis, most of the T2R genes from the three species intermingle across the tree, suggesting that some are conserved among mammals with different dietary preferences. Furthermore, one clade of bat-specific genes was detected, possibly implying that the insectivorous mammal could recognize some species-specific bitter tastants. Evolutionary analysis shows strong positive selection was imposed on this bat-specific cluster, indicating that positive selection drives the functional divergence and specialization of the bat bitter taste receptors to adapt diets to the external environment.