Amino acid sequence analysis of bitter peptides from a soybean proglycinin subunit synthesized in Escherichia coli

The cDNA encoding A1aB1b proglycinin was expressed in E. coli, for the efficient isolation of a single peptide responsible for the bitterness. The 55-kD proglycinin was highly purified, hydrolyzed, and further purified through a series of chromatographic steps to yield fractions with the major bitter peptides. The most bitter-tasting fractions contained peptides with average molecular weights lower than 1,700 Da. An analysis of the amino acid sequences indicated that many small bitter peptides (< 1,000 Da) are composed of uncharged polar amino acids as well as hydrophobic amino acids, with a charged residue often being present at either end. This suggests the involvement of a certain structural requirement in taste perception.     

Bitter Peptides in Cow Milk Casein Digests with Bacterial Proteinase

Isolation and determination of amino acid sequence of the bitter peptides formed in the digestion of cow milk casein with alkaline proteinase of Bacillus subtilis were investigated. The casein digest with the enzyme was extracted with butanol and the extracted bitter peptides were fractionally purified by treating with several other organic solvents followed by subjecting to chromatography and gel-filtration. The amino acid sequence of one of the bitter peptides was determined as follows: Arg-Gly-Pro-Pro-Phe-Ileu-Val. Liberation of N-terminal Arg with trypsin or bacterial aminopeptidase did not affect the bitterness. Also, splitting off of Val and Ileu or Ileu-Val at the C-terminus by carboxypeptidase, or a bacterial neutral proteinase gave no influence on the bitterness. However, liberation of Arg and Gly from the peptide with bacterial aminopeptidase gave rise to a non bitter peptide.     

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.     

Quantitative structure-activity relationship study of bitter di- and tri-peptides including relationship with angiotensin I-converting enzyme inhibitory activity.

Bitterness represents a major challenge in industrial application of food protein hydrolysates or bioactive peptides and is a major factor that controls the flavor of formulated therapeutic products. The aim of this work was to apply quantitative structure-activity relationship modeling as a tool to determine the type and position of amino acids that contribute to bitterness of di- and tri-peptides. Datasets of bitter di- and tri-peptides were constructed using values from available literature, followed by modeling using partial least square (PLS) regression based on the three z-scores of 20 coded amino acids. Prediction models were validated using cross-validation and permutation tests. Results showed that a single-component model could explain 52 and 50% of the Y variance (bitterness threshold) of bitter di- and tri-peptides, respectively. Using PLS regression coefficients, it was determined that hydrophobic amino acids at the carboxyl-terminus and bulky amino acid residues adjacent to the carboxyl terminal are the major determinants of the intensity of bitterness of di- and tri-peptides. However, there was no significant (p > 0.05) correlation between bitterness of di- and tri-peptides and their angiotensin I-converting enzyme-inhibitory properties.     

In Vitro Stimulation by Parathion of Porcine Pancreatic Carboxylesterase Activity toward Triacetin

In order to elucidate the relationship between bitter taste and chemical structure in peptides, various kinds of model bitter peptides containing arginine, proline and phenylalanine were synthesized, and the contribution of the individual amino acids to the bitter taste was made clear. It was confirmed that, in order to strengthen the bitterness in di- and tripeptides, the hydrophobic amino acid needs to be located at the C-terminal and, conversely, the basic amino acid should be located at the N-terminal Furthermore, a strong bitter taste was observed when arginine was contiguous to proline such as Arg-Pro, Gly-Arg-Pro and Arg-Pro-Gly. A synergistic effect for bitter taste was observed in the peptides whose structure is (Arg)_l-(Pro)_m-(Phe)_n (l=1, 2; m, n = 1 ~ 3) by increasing the number of amino acids. Among them, the octapeptide (Arg-Arg-Pro-Pro-Pro-Phe-Phe-Phe) possessed an extremely bitter taste with its threshold value of 0.002 mm and was found to be the most bitter among the peptides.     

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.     

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.     

Cross-adaptation and bitterness inhibition of L-tryptophan, L-phenylalanine and urea: further support for shared peripheral physiology

A previous study investigating individuals' bitterness sensitivities found a close association among three compounds: L-tryptophan (L-trp), L-phenylalanine (L-phe) and urea (Delwiche et al., 2001, Percept. Psychophys. 63, 761-776). In the present experiment, psychophysical cross-adaptation and bitterness inhibition experiments were performed on these three compounds to determine whether the bitterness could be differentially affected by either technique. If the two experimental approaches failed to differentiate L-trp, L-phe and urea's bitterness, then we may infer they share peripheral physiological mechanisms involved in bitter taste. All compounds were intensity matched in each of 13 subjects, so the judgments of adaptation or bitterness inhibition would be based on equal initial magnitudes and, therefore, directly comparable. In the first experiment, cross-adaptation of bitterness between the amino acids was high (>80%) and reciprocal. Urea and quinine-HCl (control) did not cross-adapt with the amino acids symmetrically. In a second experiment, the sodium salts, NaCl and Na gluconate, did not differentially inhibit the bitterness of L-trp, L-phe and urea, but the control compound, MgSO(4), was differentially affected. The bitter inhibition experiment supports the hypothesis that L-trp, L-phe and urea share peripheral bitter taste mechanisms, while the adaptation experiment revealed subtle differences between urea and the amino acids indicating that urea and the amino acids activate only partially overlapping bitter taste mechanisms.     

Degradation and debittering of a tryptic digest from beta-casein by aminopeptidase N from Lactococcus lactis subsp. cremoris Wg2.

The mode of action of purified aminopeptidase N from Lactococcus lactis subsp. cremoris Wg2 on a complex peptide mixture of a tryptic digest from bovine beta-casein was analyzed. The oligopeptides produced in the tryptic digest before and after aminopeptidase N treatment were identified by analysis of the N- and C-terminal amino acid sequences and amino acid compositions of the isolated peptides and by on-line liquid chromatography-mass spectrometry. Incubation of purified peptides with aminopeptidase N resulted in complete hydrolysis of many peptides, while others were only partially hydrolyzed or not hydrolyzed. The tryptic digest of beta-casein exhibits a strong bitter taste, which corresponds to the strong hydrophobicity of several peptides in the tryptic digest of beta-casein. The degradation of the "bitter" tryptic digest by aminopeptidase N resulted in a decrease of hydrophobic peptides and a drastic decrease of bitterness of the reaction mixture.     

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.     

Variation in Bitterness Potency When Introducing Gly-Gly Residue into Bitter Peptides

We previously reported that Gly-Gly-Arg-Pro and Arg-Pro-Gly-Gly, the derivatives of a bitter peptide Arg-Pro, had no bitterness although Gly-Arg-Pro and Arg-Pro-Gly had a bitter taste at the same level as that of Arg-Pro. To elucidate the mechanism of elimination of bitterness by the introduction of the Gly-Gly residues, we synthesized Gly-Gly derivatives of other bitter peptides such as Phe-Phe, Val-Val-Val, and Arg-Pro-Phe-Phe, and examined the effectiveness of Gly-Gly residues in eliminating bitterness. We suggest that, for Arg-Pro and Val-Val-Val, the Gly-Gly residue might prevent a hydrophobic group from binding to a taste receptor.     

Integration of QSAR modelling and QM/MM analysis to investigate functional food peptides with antihypertensive activity

Antihypertensive peptides derived from dietary proteins have long been recognised as an important source of developing functional foods with blood pressure-lowering effect. However, most of such peptides exhibit diverse tastes, such as sweet, bitter, sour and salty, which is a non-negligible aspect considered in the food development process. In the present study, several predictive quantitative structure–activity relationship (QSAR) models that correlate peptide's structural features with their multi-bioactivities and bitter taste are established at both sequence and structure levels, and the models are then used to conduct extrapolation on thousands of randomly generated, structurally diverse peptides with chain lengths ranging from two to six amino acid residues. Based on the statistical results gained from QSAR modelling, the relationship between the antihypertensive activity and bitter taste of peptides at different sequence lengths is investigated in detail. Moreover, the structural basis, energetic property and biological implication underlying peptide interactions with angiotensin-converting enzyme (ACE), a key target of antihypertensive therapy, are analysed at a complex three-dimensional structure level by using a high-level hybrid quantum mechanics/molecular mechanics scheme. It is found that (a) bitter taste is highly dependent on peptide length, whereas ACE inhibitory potency has only a modest correlation with the length, (b) dipeptides and tripeptides perform a moderate relationship between their ACE inhibition and bitterness, but the relationship could not be observed for those peptides of more than three amino acid residues and (c) the increase in sequence length does not cause peptides to exhibit substantial enhancement of antihypertensive activity; this is particularly significant for longer peptides such as pentapeptides and hexapeptides.     

Bitter Peptide Isolated from Milk Cultures of Streptococcus cremoris

Certain cultures of Streptococcus cremoris produced a bitter taste that occurred in the whey portion of milk cultures. Whey from a culture which produced bitterness was fractionated on Sephadex. The fraction in which the bitter taste was concentrated was chromatographed successively on paper with butanol-acetic acid-water (5:1:4), and then butanol-2-butanone-water (2:2:1). In each instance, the bitter component was in the most rapidly moving band that gave a positive ninhydrin test. The bitterness was observed to be caused by a peptide containing the following numbers of each amino acid: arginine, 1; glutamic acid, 2; glycine, 2; isoleucine, 2; leucine, 2; phenylalanine, 1; proline, 5; and valine, 4. N-terminal amino acids could be detected by coupling with 2,4-dinitrofluorobenzene or phenylisothiocyanate, or by hydrolysis with leucine aminopeptidase. When treated with carboxypeptidase, only leucine and valine appeared at the C-terminal end, and these were detected simultaneously.     

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.     

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.     

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.     

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.     

Removal of a Bitter Peptide from Tryptic Hydrolysates of Casein Coprecipitate by Immunoadsorbent Affinity Chromatography

Specific antibodies were prepared against a bitter peptide, which had been previously isolated from tryptic hydrolysates of casein coprecipitate. The antibodies were immobilised by covalent attachment to Sepharose 4B and the resulting immunoadsorbents were able to remove bitterness from these hydrolysates. However, it was not possible to completely remove absorbed bitter peptide from the immunoadsorbents even when using strongly deforming solvents.     

Debittering effect of Monascus carboxypeptidase during the hydrolysis of soybean protein

The actions of pepsin and the admixture of pepsin and Monascus pilosus carboxypeptidase 1 (MpiCP-1) on the hydrolysis of soybean protein were studied. The results showed that the pepsin hydrolyzate of soybean protein was much more bitter and contained relatively smaller amounts of total free amino acids than the hydrolyzate obtained with the admixture of pepsin and MpiCP-1. In addition, hydrophilic and hydrophobic amino acids were present in almost equal proportions in the pepsin hydrolyzate, while mainly hydrophobic amino acids made up the hydrolyzate obtained with the admixture of pepsin and MpiCP-1. These results suggest that MpiCP-1 suppresses and reverses the development of the bitterness taste that results from the pepsin hydrolysis of soybean protein by releasing mainly hydrophobic amino acids from the C-termini of the bitter components.     

Bitter Taste of Synthetic C-Terminal Tetradecapeptide of Bovine β-Casein,H-Pro196-Val-Leu-Gly-Pro-Val-Arg-Gly-Pro-Phe-Pro-Ile-Ile-Val209-OH,and Its Related Peptides

The primary structure of bovine β-casein contains the partial sequence of -Pro¹⁹⁶-Val-Leu-Gly-Pro-Val-Arg-Gly-Pro-Phe-Pro-Ile-Ile-Val²⁰⁹ in the C-terminal portion. We previously reported that the synthetic C-terminal octapeptide, Arg²⁰²-Val²⁰⁹, is extremely bitter with its threshold value 0.004 mm, 250 times as strong as that of caffeine. To further investigate the bitter taste of the C-terminal portion of β-casein, we synthesized the C-terminal tetradecapeptide, Pro¹⁹⁶-Val²⁰⁹, and some of its fragments. A hydrophobic hexapeptide, Pro¹⁹⁶-Val²⁰¹, was twice as bitter as caffeine. The bitter taste of the decapeptide, Pro²⁰⁰-Val²⁰⁹, was the same as that of Arg²⁰²-Val²⁰⁹. Although the tetradecapeptide, Pro¹⁹⁶-Val²⁰⁹, was composed of two bitter peptides, Pro¹⁹⁶-Val²⁰¹ and Arg²⁰²-Val²⁰⁹, its bitter taste was weaker than that of Arg²⁰²-Val²⁰⁹ and its threshold value was 0.015 mm. We suggested that the increase of bitterness in peptides through the introduction of hydrophobic amino acids depended on the number of hydrophobic amino acids added. In addition, the synthetic retro analog of Arg²⁰²-Val²⁰⁹ (H-Val-Ile-Ile-Pro-Phe-Pro-Gly-Arg-OH) was not as bitter as Arg²⁰²-Val²⁰⁹. This indicated that the sequence of Arg²⁰²-Val²⁰⁹ is important for extreme bitterness.