Bitter taste receptor T2R1 is activated by dipeptides and tripeptides

Bitter taste signaling in humans is mediated by a group of 25 bitter receptors (T2Rs) that belong to the G-protein coupled receptor (GPCR) family. Previously, several bitter peptides were isolated and characterized from bitter tasting food protein derived extracts, such as pea protein and soya bean extracts. However, the molecular targets or receptors in humans for these bitter peptides were poorly characterized and least understood. In this study, we tested the ability of the bitter tasting tri- and di-peptides to activate the human bitter receptor, T2R1. In addition, we tested the ability of peptide inhibitors of the blood pressure regulatory protein, angiotensin converting enzyme (ACE) to activate T2R1. Using a heterologous expression system, T2R1 gene was transiently expressed in C6-glioma cells and changes in intracellular calcium was measured following addition of the peptides. We found that the bitter tasting tri-peptides are more potent in activating T2R1 than the di-peptides tested. Among the peptides examined, the bitter tri-peptide Phe-Phe-Phe (FFF), is the most potent in activating T2R1 with an EC₅₀ value in the micromolar range. Furthermore, to elucidate the potential ligand binding pocket of T2R1 we used homology molecular modeling. The molecular models showed that the bitter peptides bind within the same binding pocket on the receptor. The ligand binding pocket in T2R1 is present on the extracellular surface of the receptor, and is formed by the transmembrane helices 1, 2, 3 and 7 and with extracellular loops 1 and 2 forming a cap like structure on the binding pocket.     

Sucrose Octaacetate Chemical Kinetics and Shelf Lives at Various Formulation pHs

Developing pediatric friendly dosage forms is a high priority worldwide. Sucrose octaacetate (SOA) has been recommended for use as a surrogate for bitter tasting active pharmaceutical ingredients. Even though SOA has found a number of human use applications and has been employed for decades, there are no rigorous chemical kinetic studies reported. A recently reported SOA stability-indicating method was used to perform SOA chemical kinetic and stability studies. As part of the chemical kinetic study, reaction order, activation energies, extrapolated rate constants, pH–rate profiles at 4 and 25°C, and estimated shelf lives at 4 and 25°C at different buffer pHs are provided. The estimated SOA shelf lives at 25°C and pHs 4.00, 5.20, and 6.00 were 25.3, 114, and 27.4 days, respectively. At 4°C, SOA’s estimated shelf lives were 0.478, 5.26, and 1.47 years at pHs 4.00, 5.20, and 6.00, respectively. SOA can be formulated at pHs 4 to 6 and stored at 25°C for short-duration (less than 25 days) uses such as a bitter tasting surrogate for fundamental taste mechanism studies or brief taste masking assessment clinical studies. For longer term solution studies, like being used as a bitter tasting control for blinded clinical trials, SOA should be formulated at the optimum pH of 5.40 and refrigerated at 4°C for maximum stability. The reported data can be used as a starting point for developing stable SOA formulations and estimating shelf life.     

Increased bitter taste detection thresholds in Yucatan inhabitants related to coffee as a dietary source of niacin

Persons subsisting on corn diets are at risk for pellagra, acomplex disease of malnutrition, which responds partially toniacin therapy. Coffee, once roasted and brewed, contains therapeuticlevels of niacin, but is bitter tasting. Reduced taste sensitivityto some bitter evoking substances is transmitted by a simpleMendelian process as a recessive trait. This report describesthe study of a sample of Yucatan inhabitants who used coffeeextensively and who were generally less sensitive to the bittertaste of PTC, which is possibly the result of the survival advantageconferred by being relatively less sensitive to the bitter tasteof coffee. It is speculated that a person, who is less sensitiveto bitter tastes, would consume more coffee and, thus, offsetthe deleterious effects of a niacin deficient corn diet.     

Insect antifeedant elemanolide lactones from Vernonia amygdalina

Chemical investigation of insect antifeedants from the bitter tasting leaves of Vernonia amygdalina by the application of semi-preparative reversed     

Bitter Taste of H-Pro-Phe-Pro-Gly-Pro-Ile-Pro-OH Corresponding to the Partial Sequence (Positions 61 ~ 67) of Bovine β-Casein,and Related Peptides

The bitter components of cheese are hydrophobic peptides which are produced during the process of enzymatic digestion, and some of the isolated bitter peptides are derived from the middle portion of β-casein. However, quantitative examination of the bitter taste is seldom performed. We synthesized two hydrophobic peptides, H-Pro⁶¹-Phe-Pro-Gly-Pro-Ile-Pro⁶⁷-OH and H-Tyr⁶⁰-Pro-Phe-Pro-Gly-Pro-Ile⁶⁶-OH, which correspond to common portions among the isolated bitter peptides, in order to determine how bitter they were. From the results of sensory analysis, it was found that the synthetic peptides exhibited a bitter taste with threshold values 0.25 and 0.16mm, respectively. We also synthesized their fragments and analogs, and discussed the structure-bitterness relationship.     

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.     

Debittering of protein hydrolyzates

Enzymatic hydrolysis of proteins frequently results in bitter taste, which is due to the formation of low molecular weight peptides composed of mainly hydrophobic amino acids. Methods for debittering of protein hydrolyzates include selective separation such as treatment with activated carbon, extraction with alcohol, isoelectric precipitation, chromatography on silica gel, hydrophobic interaction chromatography, and masking of bitter taste. Bio-based methods include further hydrolysis of bitter peptides with enzymes such as aminopeptidase, alkaline/neutral protease and carboxypeptidase, condensation reactions of bitter peptides using protease, and use of Lactobacillus as a debittering starter adjunct. The causes for the production of bitter peptides in various food protein hydrolyzates and the development of methods for the prevention, reduction, and elimination of bitterness as well as masking of bitter taste in enzymatic protein hydrolyzates are presented.     

Revisiting sugar-fat mixtures: sweetness and creaminess vary with phenotypic markers of oral sensation

Genetic variation in oral sensation presumably influences ingestive behaviors through sensations arising from foods and beverages. Here, we investigated the influence of taste phenotype [6-n-propylthiouracil (PROP) bitterness, fungiform papillae (FP) density] on sweet and creamy sensations from sugar/fat mixtures. Seventy-nine subjects (43 males) reported the sweetness and creaminess of water or milk (skim, whole, heavy cream) varying in sucrose (0-20% w/v) on the general Labeled Magnitude Scale. Sweetness grew with sucrose concentration and when shifting from water to milk mixtures--the growth was greatest for those tasting PROP as most bitter. At higher sucrose levels, increasing fat blunted the PROP-sweet relationship, whereas at lower levels, the relationship was effectively eliminated. Perceived sweetness of the mixture exceeded that predicted from the sum of components at low sucrose concentrations (especially for those tasting PROP most bitter) but fell below predicted at high concentrations, irrespective of fat level. Creaminess increased greatly with fat level and somewhat with sucrose. Those tasting PROP most bitter perceived greater creaminess in the heavy cream across all sucrose levels. Perceived creaminess was somewhat lower than predicted, irrespective of PROP bitterness. The FP density generally showed similar effects as PROP on sweetness and creaminess, (but to a lesser degree) and revealed potential taste-somatosensory interactions in weakly sweet stimuli. These data support that taste phenotype affects the nature of enhancement or suppression of sweetness and creaminess in liquid fat/sugar mixtures. Taste phenotype effects on sweetness and creaminess likely involve differential taste, retronasal olfactory, and somatosensory contributions to these perceptual experiences.     

Marked Increase in PROP Taste Responsiveness Following Oral Supplementation with Selected Salivary Proteins or Their Related Free Amino Acids

The genetic predisposition to taste 6-n-propylthiouracil (PROP) varies among individuals and is associated with salivary levels of Ps-1 and II-2 peptides, belonging to the basic proline-rich protein family (bPRP). We evaluated the role of these proteins and free amino acids that selectively interact with the PROP molecule, in modulating bitter taste responsiveness. Subjects were classified by their PROP taster status based on ratings of perceived taste intensity for PROP and NaCl solutions. Quantitative and qualitative determinations of Ps-1 and II-2 proteins in unstimulated saliva were performed by HPLC-ESI-MS analysis. Subjects rated PROP bitterness after supplementation with Ps-1 and II-2, and two amino acids (L-Arg and L-Lys) whose interaction with PROP was demonstrated by ¹H-NMR spectroscopy. ANOVA showed that salivary levels of II-2 and Ps-1 proteins were higher in unstimulated saliva of PROP super-tasters and medium tasters than in non-tasters. Supplementation of Ps-1 protein in individuals lacking it in saliva enhanced their PROP bitter taste responsiveness, and this effect was specific to the non-taster group.¹H-NMR results showed that the interaction between PROP and L-Arg is stronger than that involving L-Lys, and taste experiments confirmed that oral supplementation with these two amino acids increased PROP bitterness intensity, more for L-Arg than for L-Lys. These data suggest that Ps-1 protein facilitates PROP bitter taste perception and identifies a role for free L-Arg and L-Lys in PROP tasting.     

Minimum analogue peptide sets (MAPS) for quantitative structure-activity relationships

The information contents in previously published peptide sets was compared with smaller sets of peptides selected according to statistical designs. It was found that minimum analogue peptide sets (MAPS) constructed by factorial or fractional factorial designs in physiochemical properties contained substantial structure-activity information. Although five to six times smaller than the originally published peptide sets the MAPS resulted in QSAR models able to predict biological activity. The QSARs derived from a MAPS of nine dipeptides, and from a set of 58 dipeptides inhibiting angiotensin converting enzyme were compared and found to be of equal strength. Furthermore, for a set of bitter tasting dipeptides it was found that an incomplete MAPS of 10 dipeptides gave just as good a model as the model based on a set of 48 dipeptides. By comparison other non-designed sets of peptides gave QSARs with poor predictive power. It was also demonstrated how MAPS centered on a lead peptide can be constructed as to specifically explore the physiochemical and biological properties in the vicinity of the lead. It was concluded that small information-rich peptide sets MAPS can be constructed on the basis of statistical designs with principal properties of amino acids as design variables.     

Bitterness of Phenylalanine- and Tyrosine-containing Peptides

In order to investigate the role of phenylalanine and tyrosine residues in the bitter taste of peptides, some oligopeptides containing phenylalanine or tyrosine were synthesized and their taste was evaluated. The hydrophobicity of the phenylalanine or tyrosine molecule markedly caused the bitter taste in peptide. The bitterness was more intense when phenylalanine was located at the C- terminus and when the content of phenylalanine or tyrosine was increased in peptides. The hydrophobic residue in peptides functioned as a bitter taste determinant site. The experimental results suggest the existence of an additional site for the bitter taste of peptides.     

iBitter-SCM: Identification and characterization of bitter peptides using a scoring card method with propensity scores of dipeptides

In general, hydrolyzed proteins, plant-derived alkaloids and toxins displays unpleasant bitter taste. Thus, the perception of bitter taste plays a crucial role in protecting animals from poisonous plants and environmental toxins. Therapeutic peptides have attracted great attention as a new drug class. The successful identification and characterization of bitter peptides are essential for drug development and nutritional research. Owing to the large volume of peptides generated in the post-genomic era, there is an urgent need to develop computational methods for rapidly and effectively discriminating bitter peptides from non-bitter peptides. To the best of our knowledge, there is yet no computational model for predicting and analyzing bitter peptides using sequence information. In this study, we present for the first time a computational model called the iBitter-SCM that can predict the bitterness of peptides directly from their amino acid sequence without any dependence on their functional domain or structural information. iBitter-SCM is a simple and effective method that was built using the scoring card method (SCM) with estimated propensity scores of amino acids and dipeptides. Our benchmarking results demonstrated that iBitter-SCM achieved an accuracy and Matthews coefficient correlation of 84.38% and 0.688, respectively, on the independent dataset. Rigorous independent test indicated that iBitter-SCM was superior to those of other widely used machine-learning classifiers (e.g. k-nearest neighbor, naive Bayes, decision tree and random forest) owing to its simplicity, interpretability and implementation. Furthermore, the analysis of estimated propensity scores of amino acids and dipeptides were performed to provide a better understanding of the biophysical and biochemical properties of bitter peptides. For the convenience of experimental scientists, a web server is provided publicly at http://camt.pythonanywhere.com/iBitter-SCM. It is anticipated that iBitter-SCM can serve as an important tool to facilitate the high-throughput prediction and de novo design of bitter peptides.     

EXPLORATION OF THE SENSORY CHARACTERISTICS OF CRAVED AND AVERSIVE FOODS

This research examined the sensory characteristics of craved and aversive foods, as determined by 70 healthy adults. Cravings and aversions were identified by 66% and 53% of subjects. Typically, cravings were intermittent, and the items were sweet tasting and pleasant smelling. In contrast, aversions were chronic, and the items were described as either bitter or bad (e.g., soapy, mealy, dusty) tasting, and exhibiting an unpleasant smell. Chemesthetic attributes were frequently associated with cravings and aversions, particularly texture and thermal sensations with the former whereas texture and irritating sensations were associated with the latter. The findings suggest that sensory characteristics of foods may provide salient cues for the formation of cravings and aversions.     

Formation of Dendrolasin,Sesquirosefuran, Perillene and Rosefuran by Biomimetic Autooxidation

To estimate the steric distance between the bitter taste determinant sites in peptides, some cyclic dipeptides, amino acid anilides, amino acid cyclohexylamides, and benzoyl amino acids were synthesized and their tastes were evaluated. The diketopiperazine ring of cyclic dipeptides acted as a bitter taste determinant site due to its hydrophobicity. The steric distance between 2 sites was estimated as 4.1 Å from the molecule models of cyclic dipeptides composed of typical amino acids in the bitter peptides. Due to the hypothesis of two bitter taste determinant sites, which bind with the bitter taste receptor via a “binding unit” and a “stimulating unit,” a mechanism for the bitterness in peptides was postulated.     

Inducibility of Aryl Hydrocarbon Hydroxylase Activity in Cultured Cell as Food-screening for Safety Assessment

In order to investigate the effect of leucine residues on the taste of peptides, some oligo peptides containing leucine residues were synthesized and their taste was evaluated. The hydrophobicity of leucine residues markedly caused the bitterness of peptides and stronger bitterness was always found when a leucine residue was located at the C-terminus of peptides. The possibility of 2 binding sites between the bitter peptides and the bitter taste receptors of the gustation cells was postulated.     

Isolation of Bitter Peptides from Tryptic Hydrolysate of Casein and their Chemical Structure

Bitter peptides were isolated from the tryptic hydrolysate of casein. Fractionation and isolation were carried out using n-butanol extraction, acidic precipitation at pH 5.4, gel filtration with Sephadex G-25, ion exchange chromatography with Dowex 50 W and paper chromatography. Three kinds of bitter peptides were purified. The primary structures of these peptides were proposed as follows; BP-I, Gly-Pro-Phe-Pro-Val-Ileu; BP-II, Phe-Phe-Val-Ala-Pro-Phe-Pro-Glu-Val-Phe-Gly-Lys; BP-III, Phe-Ala-Leu-Pro-Gln-Tyr-Leu-Lys. These peptides were very bitter in a 0.1% solution.

l-Tyrosine, l-phenylalanine and their derivatives were also tasted. The importance of the position of bitter amino acids in the peptide in the development and strengthening of its bitter taste is discussed.     

Individual differences in perception of bitterness from capsaicin, piperine and zingerone

It was recently shown that in some subjects capsaicin can evoke bitterness as well as burning and stinging, particularly in the circumvallate (CV) region of the tongue. Because perception of bitterness from capsaicin is characterized by large individual differences, the main goal of the present study was to learn whether people who taste capsaicin as bitter also report bitterness from structurally similar sensory irritants that are known to stimulate capsaicin-sensitive neurons. The irritancy and taste of capsaicin and two of its most commonly studied congeners, piperine and zingerone, were measured in individuals who had been screened for visibility of, and reliable access to, the CV papillae. Approximately half of these individuals reported tasting bitterness from all three irritants when the stimuli were swabbed directly onto the CV papillae. Concentrations that produced similar levels of burning sensation across subjects also produced similar (though lower) levels of bitter taste. These results are consistent with the hypothesis that capsaicin and its congeners stimulate bitterness via a common sensory receptor that is distributed differentially among individuals. Additionally, bitter tasters rated gustatory qualities (but not burning and stinging) slightly but significantly higher than did bitter non-tasters, which suggests that perception of capsaicin bitterness is associated with a higher overall taste responsiveness (but not chemesthetic responsiveness) in the CV region.     

Relationship between Bitterness of Peptides and their Chemical Structures

Various peptides and derivatives of peptides and amino acids were synthesized and tasted, systematically, to elucidate the relationship between bitterness and chemical structures of peptides.

We have found that: 1. Peptides become more bitter than the original amino acids when their amino and carboxyl groups are blocked and when peptide bond is formed. 2. A peptide molecule with a high content of amino acids with hydrophobic side chains will develop bitter taste. 3. The amino acids in a peptide chain independently contribute to bitterness regardless of amino acid sequences and configuration.