Beef Protein-Derived Peptides as Bitter Taste Receptor T2R4 Blockers

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Chemistry and Biology of Aroma and Taste

Beef Protein-Derived Peptides as Bitter Taste Receptor T2R4 Blockers Chunlei Zhang, Monisola Alashi, Nisha Singh, Kun Liu, Prashen Chelikani, and Rotimi E. Aluko J. Agric. Food Chem., Just Accepted Manuscript • DOI: 10.1021/acs.jafc.8b00830 • Publication Date (Web): 29 Apr 2018 Downloaded from http://pubs.acs.org on April 30, 2018

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Journal of Agricultural and Food Chemistry

Beef Protein-Derived Peptides as Bitter Taste Receptor T2R4 Blockers Chunlei Zhang,† Monisola A. Alashi,† Nisha Singh,‡,Φ Kun Liu,‡,Φ Prashen Chelikani,*,‡,Φ and Rotimi E. Aluko*,†,§,Φ



Department of Food and Human Nutritional Sciences, University of Manitoba, Winnipeg,

Manitoba, Canada R3T 2N2 ‡

Department of Oral Biology, University of Manitoba, Winnipeg, Manitoba, Canada R3E 0W2

§

Richardson Center for Functional Foods and Nutraceuticals, University of Manitoba, Winnipeg,

Manitoba, Canada R3T 2N2 Φ

Manitoba Chemosensory Biology (MCSB) research group, University of Manitoba, Winnipeg,

Manitoba, Canada R3E 0W2

Corresponding Authors *Phone: +1 204 474 9555. E-mail: [email protected] *Phone: +1 204 789 3539. E-mail: [email protected]

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ABSTRACT: The aim of this work was to determine the T2R4 bitter taste receptor-blocking

2

ability of enzymatic beef protein hydrolysates and identified peptide sequences. Beef protein was

3

hydrolyzed with each of six commercial enzymes (alcalase, chymotrypsin, trypsin, pepsin,

4

flavourzyme, and thermoase). Electronic tongue measurements showed that the hydrolysates had

5

significantly (p < 0.05) lower bitter scores than quinine. Addition of the hydrolysates to quinine

6

led to reduced bitterness intensity of quinine with trypsin and pepsin hydrolysates being the most

7

effective. Addition of the hydrolysates to HEK293T cells that heterologously express one of the

8

bitter taste receptors (T2R4) showed alcalase, thermoase, pepsin and trypsin hydrolysates as the

9

most effective in reducing calcium mobilization. Eight peptides that were identified from the

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alcalase and chymotrypsin hydrolysates also suppressed quinine-dependent calcium release from

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T2R4 with AGDDAPRAVF and ETSARHL being the most effective. We conclude that short

12

peptide lengths or the presence of multiple serine residues may not be desirable structural

13

requirements for blocking quinine-dependent T2R4 activation.

14 15

KEYWORDS: bitterness, protein hydrolysates, bitter taste receptor, (T2R), peptides, quinine,

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electronic tongue

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INTRODUCTION

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Human beings are naturally averse to bitter taste because of the non-pleasant oral sensation

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coupled with the fact that some causative compounds are usually toxic and may be life-

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threatening.1,2 Therefore, eliminating or reducing the bitter taste attribute of pharmaceutical and

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food products could enhance organoleptic properties and consumer acceptance. Bitter taste is

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sensed by 25 bitter taste receptors (T2Rs), which are responsible for human perception of

30

thousands of bitter-tasting substances.3-7 The genes that code for the T2R proteins, are referred to

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as TAS2Rs (HUGO gene nomenclature). So far, only a few antagonists or blockers against

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specific T2Rs have been identified to work at the receptor level to reduce bitterness intensity of a

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limited number of food products8-13, and these compounds have been extensively reviewed

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recently.14 Therefore, discovery of additional bitter blockers are required in order to expand

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coverage of several other foods that require bitter taste masking, especially for improved

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commercial success. A diversity of bitter taste-blocking compounds will also enable

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determination of structural properties that enhance interactions with T2Rs to block activation by

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bitter substances. However, due to the limited understanding of the mechanism of bitter taste

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signal transduction, progress towards production and utilization of new blockers has been slow.

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This is complicated by the fact that in addition to the oral cavity, T2Rs are also expressed in the

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brain, skin, thyroid gland, large intestine, testis, nasal epithelium and human airway.11,15-19 These

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extraoral T2Rs are believed to participate in various physiological functions and are considered

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potential therapeutic targets for diseases such as those that affect the respiratory airway,

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especially asthma-related dysfunctions.20-22

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Bioactive peptides that are generated from enzymatic hydrolysis of food proteins are

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increasingly gaining attention because they have been reported to possess multifunctional health-

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promoting properties that include bitterness, antihypertensive, anti-inflammatory and anticancer

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activities.23-26 However, there is limited information on bitterness-suppressing properties of food

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protein hydrolysates and their constituent peptide chains. Previous studies have reported that

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amino acids and peptides have the capacity to efficiently diminish bitter taste intensity. For

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example, L-aspartyl-L-phenylalanine and L-ornithyl-L-alanine were reported to reduce the

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bitterness of potassium chloride.27 In addition to protein hydrolysates, other compounds such as

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simple nucleotides cytosine

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demonstrated to cause a 40% and 60% reduction in bitterness of a 10 mM quinine solution,

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respectively.28 However, quantitative data and the mechanisms of bitter taste suppression by

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amino acids and peptides remain scarce. Beef proteins have been shown to generate (through

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enzymatic hydrolysis) desirable flavor-promoting peptides.29,30 Thus, we envisaged that beef

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protein could also be an excellent raw material to generate peptides with bitter taste-blocking

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properties. Therefore, the aim of this work was to determine the T2R4 bitter taste receptor-

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blocking ability of enzymatic meat protein hydrolysates followed by elucidation of the structural

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and functional properties of the main peptides.

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MATERIALS AND METHODS

monophosphate and 2-deoxyadenosine triphosphate were

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Materials. Ground beef was purchased from a local market (Safeway, Winnipeg, Manitoba,

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Canada). Chymotrypsin® (from bovine pancreas, EC 3.4.21.1), trypsin® (from porcine pancreas,

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EC 3.4.21.4), Pepsin® (from porcine gastric mucosa, EC 3.4.23.1), Alcalase® (from fermentation

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of Bacillus licheniformis, EC 3.4.21.62), and Flavourzyme® (from Aspergillus oryzae, EC

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232.752.2) were all purchased from Sigma-Aldrich (St. Louis, MO, USA). Thermoase® (from

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Bacillus stearothermophilus, EC 3.4.24.27) was a product of Amano Enzymes Inc. (Nagoya,

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Japan). Electronic tongue instrument diagnostic solutions including hydrochloride (0.1 M HCl), 4 ACS Paragon Plus Environment

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sodium chloride (0.1 M NaCl) and monosodium glutamate (0.1 M MSG) as well as the

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calibration solution (1 M HCl) were purchased from Alpha M.O.S (Toulouse, France). Known

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bitter score substances such as acetaminophen, caffeine monohydrate, quinine hydrochloride

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(QHCl), leporamide hydrochloride and femotidine were purchased from MP Biomedicals (Solon,

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OH, USA). Quinine and BCML (Nα,Nα-bis(carboxymethyl)-l-lysine) was from Sigma Aldrich

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(St. Louis, MO, USA).

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Preparation of beef protein hydrolysates (BPHs). Raw ground beef (approximately 250 g)

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was evenly packed into aluminum foil plates, frozen at -20 °C for 24 h and then freeze-dried.

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The freeze-dried beef was blended thereafter in a Waring blender to fine powder and defatted

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repeatedly by mixing 100 g with 1 L food grade acetone. The mixture was continually stirred for

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3 h in fume hood and decanted manually followed by two consecutive extractions of the

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residues. The defatted beef (DB) was placed in aluminum foil plates and air-dried overnight in

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the fume hood at room temperature. The DB was milled in the Waring blender into fine powder

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and stored at -20 °C. DB was then mixed with water to prepare a (w/v) 5% suspension followed

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by addition of an enzyme (1%, w/w, protein weight basis) to initiate protein hydrolysis. The

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hydrolysis conditions (temperature and pH) of each enzyme were based on manufacturers’

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instructions and literature information.31-33 For alcalase hydrolysis, the DB suspension was

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heated to 55°C and adjusted to pH 8.0 using 2 M NaOH. The DB suspensions for trypsin,

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chymotrypsin and thermoase hydrolysis were first heated to 37 °C and then adjusted to pH 8.0.

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For flavourzyme and pepsin hydrolysis, the DB suspension was heated to 50 °C and 37 °C

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followed by adjustment to pH 6.5 and 2.0, respectively. Each mixture was stirred continuously

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for 4 h and the reaction terminated by heating at 95 °C for 15 min. The reaction mixtures were

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thereafter centrifuged (3,270g at 4 °C) for 30 min and the resulting supernatants freeze-dried as

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the BPHs and stored at -20 °C.

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Determination of degree of hydrolysis (DH). The DH of various BPHs was determined by

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the O-phthalic aldehyde (OPA) method, which was based on previous reports.34,35 The OPA

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reagent, which was prepared fresh daily contained 6 mM OPA dissolved in 95% methanol and

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5.7 mM DL-dithiothreitol in 0.1 M sodium tetraborate decahydrate with 2% (w/v) SDS. N-Gly-

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Gly glycine solution was prepared as standard in 8 serial concentrations (0.05-0.4 mg/mL) while

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DB and BPHs were prepared in distilled water at 0.25 mg/mL. Ten µL of the standard solutions,

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DB or BPH were pipetted into microplate wells followed by addition of 200 µL of OPA reagent.

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Absorbance of the standard and samples were then read at 340 nm and 37°C in a Synergy H4

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multi-mode plate reader (Biotek Instruments, Winooski, Vermont, USA). The total amino groups

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in the DB were determined using a sample that has been subjected to 6 M HCl hydrolysis at

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110 °C for 24 h. The DH was calculated by the following equation: %‫ = ܪܦ‬ሾሺሺܰ‫ܪ‬ଶ ሻ஻௉ு ሻ − ሺܰ‫ܪ‬ଶ ሻ஽஻ /ሺሺܰ‫ܪ‬ଶ ሻ ்௢௧௔௟ − ሺܰ‫ܪ‬ଶ ሻ஽஻ ሻሿ ∗ 100

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(NH2) BPH: Content of free amino groups in BPH

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(NH2) DB: Content of free amino groups in DB

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(NH2) Total: Content of free amino groups in acid hydrolyzed DB

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Analysis of amino acid composition. The amino acid profiles of DB and BPH were

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determined according the method of Bidlingmeyer,36 using an HPLC system to analyze amino

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acid composition of samples that have been hydrolyzed with 6 M HCl for 24 h. The contents of

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cysteine and methionine were measured after performic acid oxidation37 while tryptophan

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content was determined after alkaline hydrolysis.38

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Estimation of molecular weight distribution. Molecular weight distribution of BPHs was

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determined based on the method described by He et al.,39 using an AKTA FPLC system (GE

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Healthcare, Montreal, PQ) equipped with a Superdex Peptide12 10/300 GL column 154 (10 x

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300 mm) and UV detector (λ = 214 nm). The column was calibrated using the following standard

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proteins and an amino acid: cytochrome C (12,384 Da); aprotinin (6,512 Da); vitamin, 855 Da);

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and glycine (75 Da). A 100 µL aliquot of the 5 mg/mL BPH sample (dissolved in 50 mM

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phosphate buffer, pH 7.0 containing 0.15 M NaCl) was loaded onto the column and elution

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performed at room temperature using the phosphate buffer at a flow rate of 0.5 mL/min. The

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molecular weights (MW) of peptides in samples were estimated from a linear plot of log MW

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versus elution volume of standards.

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Estimation of bitter scores by electronic-tongue (e-tongue). Each BPH was dissolved in

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distilled water to give 0.5, 1.0, 2.5, 5.0, and 10.0 mg/mL concentrations followed by filtration

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first through a 0.45 µm filter disc and then a 0.2 µm filter. Bitter scores of filtered BPH solutions

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(20 mL) were evaluated using the Astree II E-tongue system (Alpha M.O.S., Toulouse, France).

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This system is a completely automated taste analyzer equipped with seven sensors, BD, EB, JA,

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JG, KA, OA, and JE, based on the ChemFET technology (Chemical modified Field Effect

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Transistor) to analyze liquid samples. Firstly, 0.01 M HCl was used to condition and calibrate

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sensors and the reference electrode repeatedly until stable signals were obtained for all seven

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sensors with minimal or no noise and drift. Secondly, diagnostic procedure was performed

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repeatedly using 0.1 M HCl, NaCl, and MSG to ensure the sensors can identify distinctive tastes,

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until the discrimination index achieved at least 0.94 on a principle component analysis map.

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Thereafter, the partial least square (PLS) regression bitterness standard model was constructed

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using several bitter taste compounds with known bitter taste scores determined from human

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panelists, including 0.24 mM and 2.36 mM caffeine, 0.03 mM and 0.12 mM quinine, 0.44 mM

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and 0.88 mM prednisolone, as well as 3.31 mM and 19.85 mM paracetamol (Figure S1).

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Validation of the PLS model was achieved with 0.002 mM and 0.01 mM loperamide followed by

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0.06 mM and 0.15 mM famotidine according to the manufacturer’s instructions.40 A series of

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BPH concentrations (0.5 mg/mL, 1 mg/mL, 2.5 mg/mL, 5 mg/mL, and 10 mg/mL) were

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prepared, filtered as indicated above and then used to determine the e-Tongue threshold. The 5

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mg/mL sample was determined as the maximum strength useful to evaluate BPH bitterness

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intensity and this concentration was subsequently used to obtain bitter scores. In order to

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evaluate the bitterness suppressing ability of protein hydrolysates, the T2R4 agonist quinine and

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BPH solutions were mixed to obtain 1 mM and 5 mg/mL concentrations, respectively. As a

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positive control, the known T2R4 bitter taste blocker Nα,Nα-bis(carboxymethyl)-l-lysine (BCML)

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with an IC50 of 59 nM for quinine were mixed together to obtain 59 nM (BCML) and 1 mM

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(quinine) final concentrations, respectively. For all samples, triplicate analysis of each solution

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was performed.

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Determination of cellular calcium mobilization. Determination of the potential bitter taste-

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activating or blocking activity of BPH was carried out by measuring intracellular Ca2+

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mobilization using Fluo-4 NW calcium assay kit as previously described.3 Stable transfected

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HEK293 cells expressing TAS2R4 and G-alpha 16/44 or HEK293T cells expressing only G-

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alpha 16/44 were used as experimental and negative control group, respectively. Approx. 1×105

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cells/ well plated in the 96-well BD-falcon biolux plate and then incubated at 37 °C in a CO2

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incubator for 16 h. After incubation, the culture medium was substituted (for 40 min at 37 °C in

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the CO2 incubator followed by 30 min incubation at room temperature) with Fluo-4 NW dye

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solution, which contained lyophilized dye in 10 mL of assay buffer (1x Hanks’ balanced salt

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solution, 20 mM HEPES) and 100 µL 2.5 mM probenecid added to prevent dye leakage from

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cytosol. Calcium mobilization was measured in terms of relative fluorescence units (RFUs) using

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a Flexstation-3 microplate reader (Molecular Devices, CA, USA) at 525 nm, following 494 nm

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excitation. Based on the e-tongue data, BPH at 5 mg/mL, BCML at 59 nM and agonist quinine at

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1 mM were used individually or in combination with peptides to determine T2R4 activation.

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BPH or BCML was then mixed with quinine (1 mM final concentration) to obtain 5 mg/mL or

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59 nM, respectively and used to determine inactivation of T2R4. The basal intracellular calcium

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levels were measured for the first 20 s followed by addition of appropriate concentration of

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ligands for another 120 s. To get the absolute RFUs, the basal RFU before adding the ligand,

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which was labeled minimum value (Min) was deducted from the maximum RFU (Max) obtained

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after stimulating with the ligand (absolute RFUs = Max – Min). Next, the signals from the

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negative control group cells were subtracted from the observed signal of experimental group

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cells to give ∆RFUs. Data were collected from two independent experiments, each done in

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triplicate. PRISM software version 4.03 (GraphPad Software, San Diego) was used for data

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analysis.

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Separation of BPH by reversed-phase high-performance liquid chromatography (RP-

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HPLC). Alcalase hydrolysate (AH) and chymotrypsin hydrolysate (CH), the two most active

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bitter taste blockers were subjected to RP-HPLC separation on a 21 x 250 mm C12 preparative

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column (Phenomenex Inc., Torrance, CA, USA) attached to a Varian 940-LC system (Agilent

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Technologies, Santa Clara, CA, USA) according to the method of Girgih et al.41 Briefly, freeze-

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dried AH or CH was dissolved in double distilled water that contained 0.1% trifluoroacetic acid

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(TFA) as buffer A to give 100 mg/mL. After sequential filtration through 0.45 µm and 0.2 µm

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filters, 4 mL of the sample solution was injected onto the C12 column. Fractions were eluted

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from the column at a flow rate of 10 mL/min using a linear gradient of 0–100% buffer B

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(methanol containing 0.1% TFA) over 60 min. Peptide elution was monitored at 214 nm, eluted

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peptides were collected using an automated fraction collector every 1 min and pooled into four

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fractions according to elution time. In this study, according to the distribution of peaks of

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chromatograms, 4 fractions each were collected from AH (AH-F1, AH-F2, AH-F3, AH-F4) and

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CH (CH-F1, CH-F2, CH-F3, CH-F4). The solvent in the pooled fractions was evaporated using a

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vacuum rotary evaporator maintained at a temperature range between 35 and 45 oC and thereafter

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the aqueous residue was freeze-dried. Fractionated peptides were analyzed for calcium

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mobilization ability using the cell culture protocols described above. The most active fractions

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(AH-F1 and CH-F4) were each subjected to a second round of RP-HPLC separation using

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peptide load (400 mg), C12 preparative column, elution buffers, flow rate and detection

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wavelength as used in the first round of separation. Elution was carried out with a linear gradient

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of 0–35% buffer B in buffer A over 49 min. Eluted peptides were collected using an automated

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fraction collector every 1 min and pooled into 4 AH-F1 fractions and 8 CH-F4 fractions. The

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solvent in each fraction was removed under vacuum in a rotary evaporator and the aqueous

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residues freeze-dried and used for calcium mobilization experiments as described above.

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Peptide identification and sequencing. The most active fractions (AH-F1-3, CH-F4-3, CH-

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F4-5) against T2R activation (calcium mobilization experiments) from the second RP-HPLC

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separation peptide fractions were analyzed by tandem mass spectrometry. Briefly, a 10 ng/µL

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aliquot of the sample (dissolved in an aqueous solution of 0.1% formic acid) was infused into an

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Absciex QTRAP® 6500 mass spectrometer (Absciex Ltd., Foster City, CA, USA) coupled to an

203

electrospray ionization (ESI) source. Operating conditions were 5.5 kV ion spray voltage at 200

204

o

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MS/MS spectra were analyzed using PEAKS 7.0 Studio software (Bioinformatics Solutions,

C, and 30 µL/min flow rate for 2 min in the positive ion mode with 2000 m/z scan maximum.

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Waterloo, ON, Canada) to obtain peptide sequences. The identified peptides were chemically

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synthesized (>95% purity) by Genscript Inc. (Piscataway, NJ, USA).

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Statistical analysis. Data analyses were performed made using one-way analysis of variance

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(ANOVA) with an IBM SPSS Statistical package (version 20). Mean values were compared

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using the Duncan Multiple Range Test and significantly differences accepted at p < 0.05.

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RESULTS AND DISCUSSION

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Degree of hydrolysis. As shown in Table 1, the DH of the protein hydrolysates was enzyme-

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dependent with the highest values for microbial enzymes (alcalase and flavourzyme). The high

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DH for flavourzyme may have been due to the presence of endoproteases and exoproteases,42

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which could have enhanced the rate of proteolysis. The results are similar to those previously

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reported for bovine plasma proteins where the flavourzyme hydrolysates had higher DH values

217

than the alcalase hydrolysates.43 Similarly, Kane et al.44 reported a slightly higher DH for a

218

peanut hydrolysate produced from flavourzyme when compared to that of alcalase after

219

hydrolysis for 4 h. However, the results are different from those reported for tilapia muscle

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protein hydrolysis where the flavourzyme produced lower DH than alcalase.34 An interesting

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outcome is that the intestinal enzymes (trypsin and chymotrypsin) digested the meat proteins

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more efficiently and produced hydrolysates with higher DH than the stomach enzyme, pepsin.

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Amino acid composition. In comparison to the defatted beef protein, significant changes in

224

some of the amino acids were observed after enzymatic hydrolysis (Table 2). Glutamic acid +

225

glutamine (Glx) were the most abundant in the beef but there was no significant change in

226

content after protein hydrolysis. In contrast, the contents of aspartic acid + asparagine (Asx) and

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arginine were significantly (p < 0.05) enhanced in the protein hydrolysates. However, the protein

228

hydrolysates had significantly reduced levels of cysteine, methionine and tryptophan. Kohl et 11 ACS Paragon Plus Environment

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al.45 had previously shown that tryptophan is a T2R4 agonist. Therefore, protein hydrolysates

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with lower tryptophan levels may provide a better source of weakly-acting T2R4 peptide

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agonists or even antagonists when compared to those with higher levels. With respect to amino

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acid groups, there were overall significant (p < 0.05) reductions in hydrophobic amino acids,

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aromatic amino acids and sulfur-containing amino acids after the enzymatic protein hydrolysis.

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But positively-charged amino acids were significantly (p < 0.05) higher in the protein

235

hydrolysates when compared to the defatted beef protein. A previous work has shown that the

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peptide’s amino acid side groups may be more important than the amino and carbonyl groups

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during T2R4 activation.45 Therefore, the results reflect the different proteolytic specificities of

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the proteases used in this work, which provided a wide variation of peptides (different side

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groups) that could function as T2R4 antagonists.

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Gel-permeation chromatography. Peptide size distribution indicates the presence of mostly

241

peptides with the main peaks between 0.445-3.2 kDa (Figure 1). Alcalase hydrolysate (AH) had

242

the most uniform peptide distribution followed by chymotrypsin hydrolysate (CH) while the

243

remaining hydrolysates had big peptide peaks with estimated MW of 116-132 kDa. Alcalase is

244

an endopeptidase with very high degree of proteolysis, which may have contributed to the almost

245

normal distribution of low molecular weight peptides. However, unlike the other hydrolysates

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the flavourzyme hydrolysate (FH) had a distinct big peak with ~60 Da estimated MW, which

247

most likely represents amino acids due to the presence of exopeptidase activity. Peptide size and

248

amino acid composition play an important role in taste. This is because previous studies have

249

reported that peptides of 0.36-2.10 kDa were primary contributors to bitterness of protein

250

hydrolysates, because smaller peptides failed to achieve the particular conformation required for

251

binding to taste receptors.46,47 The results suggest that peptide sizes identified from this work fall

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within the 0.36-2.10 kDa range and can interact with bitter taste receptors.

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Prediction of bitter score from e-tongue. Electronic-tongues have been widely used to

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detect bitter taste of samples, but also can determine the suppression ability of bitter taste

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modifiers, such as high potency sweeteners suppressing bitter taste of quinine hydrochloride, and

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acesulfame K and citric acid suppressing the bitter taste of epinephrine.48,49 Quinine can activate

257

multiple T2Rs50 and therefore, is a suitable compound to test for antagonists or bitter taste

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suppressors. Figure 2 shows e-tongue bitterness scores for individual beef protein hydrolysates

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and their combinations with quinine. Quinine had the strongest bitterness intensity while the

260

inverse agonist for T2R4 (BCML) had the least (p < 0.05). Among the hydrolysates, AH had the

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least bitterness intensity (p < 0.05) while there were no significant differences between the

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remaining five hydrolysates. The lower bitterness intensity of the AH may be attributed to two

263

main factors. First, is the higher DH (compared to the other hydrolysates), which could have

264

enhanced further proteolysis to split very bitter and larger peptides to produce smaller peptides

265

with reduced bitter-taste. This is consistent with the lower molecular weight profile (~445 Da) of

266

the AH peptides when compared to the other hydrolysates (Figure 1). The possibility of using

267

extensive proteolysis to decrease protein hydrolysate bitterness has also been discussed.51 Second,

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the sum of hydrophobic amino acids (HAA) and positively-charged amino acids (PCAA) has

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been reported to be important for enhancing bitterness intensity of peptides.52 AH and FH had

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the lowest sum of HAA + PCAA but it can be concluded that FH has less content of peptides and

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more free amino acids due to the exopeptidase activity in flavourzyme. Therefore, the lower

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bitterness intensity of AH may also be due to the reduced contents of PCAA and HAA. The

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results are consistent with previous works that have reported enzymatic food protein

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hydrolysates usually have bitter taste (Humiski and Aluko).47,53,54 In the presence of BCML and

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each of the protein hydrolysates, bitterness intensity of quinine was significantly (p < 0.05)

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decreased. BCML produced the most decrease in quinine bitterness intensity followed by TH and

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PH. The structural basis for the bitter taste blocking efficiency of the hydrolysates is difficult to

278

determine because of the presence of a large pool of peptides. However, it is pertinent to note

279

that the TH had the lowest content of HAA while PH had the least content of negatively-charged

280

amino acids.

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Inhibition of quinine-dependent T2R4 activation by protein hydrolysates. In previous

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studies that examined small molecular weight bitter taste modifiers, TAS2R4 gene was

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heterologously expressed in HEK293T cells and intracellular calcium mobilization assay has

284

been applied to measure the bitterness inhibitory ability of the compounds.8-10 In this assay, high

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intracellular calcium mobilization means that the T2Rs are activated more intensely, while lower

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calcium releases suggest weak activation. Results from the calcium mobilization assay indicate

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highest activity for quinine, CH and FH (Figure 3). In contrast, TH, PH, TMH and AH were

288

significantly less effective in inducing intracellular calcium mobilization in T2R4 expressing

289

cells. The low calcium mobilization ability of AH is consistent with the lowest bitterness

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intensity among the hydrolysates as determined by e-tongue. However, the calcium mobilization

291

ability of the remaining five hydrolysates was not related to the e-tongue data. The uniform

292

peptide size distribution in AH when compared to the other hydrolysates with non-uniform size

293

distribution may have contributed to this discrepancy. The results suggest that high molecular

294

weight peptides (more abundant in FH, CH, TH, PH and TMH) behave differently from smaller

295

molecular weight peptides (more abundant in AH) with respect to electrochemical signaling

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properties in the e-tongue and biological interactions with the T2R4. Moreover, previous reports

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have suggested the e-tongue instrument appears to have difficulty in sensing organic bitter taste

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substances, such as amino acids and peptides; therefore, a wider variation in peptide size could

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have exacerbated this deficiency.55,56 Because the e-tongue responses varied from those of the

300

calcium mobilization assay, the least effective (AH) and most effective (CH) in causing calcium

301

release from T2R4 cells were chosen for peptide identification through RP-HPLC separation to

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obtain 4 fractions each (Figure 4). Moreover, protein hydrolysates contain a wide range of

303

peptides and measured properties such as bitterness intensity only reflect net activity. Therefore,

304

the protein hydrolysates could still contain individual peptides with T2R4 antagonistic property

305

that was masked by other peptides during the e-tongue experiments, hence the need for peptide

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fractionation and sequence identification. The AH-F1 was the most effective in blocking

307

quinine-dependent calcium release in the T2R4 expressing HEK293T cells while the four CH

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fractions behaved similarly to each other. However, CH-F4 was chosen for further peptide

309

fractionation due to higher abundance when compared to CH-F1, CH-F2 and CH-F3. AH-F1

310

separation on the RP-HPLC column also led to 4 isolated fractions with the AH-F1-3 producing

311

the most significant (p < 0.05) blockage of quinine-dependent calcium release from T2R4

312

expressing HEK293T cells (Figure 5). In contrast, RP-HPLC separation of CH-F4 yielded 8

313

fractions, all which produced significant (p < 0.05) reductions in calcium release when added to

314

quinine (Figure 6). However, CH-F4-1, CH-F4-3, CH-F4-4 and CH-F4-5 had the most

315

reductions in calcium release. Based on absolute values of the decrease in calcium release, AH-

316

F1-3, CH-F4-3 and CH-F4-5 were chosen for peptide identification and amino acid sequencing.

317

Inhibition of quinine-dependent T2R4 activation by synthesized peptides. Four peptides

318

were identified from AH-F1-3, one from CH-F4-3 and three from CH-F4-5 with sequences

319

shown in Table 3 and supplementary Figures S1-S8. Threonine, serine, methionine, leucine, and

320

alanine were the most common amino acids in the peptides. With the exception of AAMY and

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AAYM, the ratio of hydrophobic amino acids in each identified peptides was less than 50%,

322

which suggest that hydrophilic characteristics may have contributed to the bitter taste-

323

suppressing ability of these peptides. However, it has been suggested that hydrophobic properties

324

can enhance peptide entry into target organs through cell membrane lipid bilayer,57 which

325

contributes to enhanced bioactivity inside the cells. Besides, some hydrophobic compounds such

326

as D-Tryptophan benzyl ester and N,N-Dibenzyl-L-serine methyl ester, were reported to have

327

high predicted antagonistic binding affinity to T2R4,8 implying that it is possible for

328

hydrophobic substances to inhibit bitter taste receptors. Thus, peptides with high contents of

329

hydrophobic amino acids may also have ability to suppress bitterness.

330

All peptides showed significantly (p < 0.05) lower calcium mobilization than quinine

331

(Figure 7). Peptides ETSARHL, ETCL, AGDDAPRAVF and AAMY showed less calcium

332

mobilization (∆RFU) upon co-incubation with quinine in HEK293T cells expressing T2R4

333

indicating that these four peptides may have triggered calcium mobilization through a T2R4-

334

dependent pathway. Next, competition assays on T2R4 were pursued using three of the peptides

335

to obtain their inhibitory concentrations (IC50). Result showed that these peptides inhibited

336

quinine response in a concentration dependent manner, with AGDDAPRAVF showing a lower

337

IC50 value of 85 µM among the three peptides analyzed (Figure 8).

338

It has been observed in several soybean protein-derived peptides that leucine residue at

339

C-terminal was responsible for bitterness; treatment with a carboxypeptidase led to a marked

340

reduction in bitterness intensity.58,59 Hence the peptides AGDDAPRAVF, AAMY, VSSY,

341

AAYM should have less bitter taste compared to other identified peptides with leucine residue at

342

C-terminal. But the results obtained in this work do not agree with such hypothesis because the

343

leucine-containing peptides (especially ETCL), had similar or even lower calcium release ability

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than peptides that did not contain leucine (Figure 7). Addition of each peptide to quinine led to

345

significant reductions (except VSSY) in calcium release from the T2R4-expressing cells with

346

AGDDAPRAVF being the most effective blocker. The two peptides with multiple numbers of

347

serine residues were not very effective, which suggests that this amino acid may not be an

348

important structural requirement for bitter taste-blocking peptides. However, the number of

349

peptides studied in this work is too small to estimate structure-function properties. But it is

350

important to point out that the two most active suppressors of quinine bitter taste are also the

351

longest peptide chains, which could indicate an importance for the number of amino acids.

352

In conclusion, this work has revealed the potential to use beef protein hydrolysates and

353

derived peptides as bitter taste T2R4 receptor blockers. Recent studies have revealed that T2Rs

354

are also expressed in the gastrointestinal tract, enteroendocrine STC-1 cells, respiratory system,

355

male reproductive system, central nervous system and several tissues.60-62 This development

356

suggests that T2Rs may possess more potential important physiological functions other than

357

bitter taste sensation. For example, most drugs have bitter taste, which may be responsible for

358

some of the observed off-target (or negative) effects since these drugs can activate T2Rs in non-

359

target parts of the body. Therefore, in addition to enhancing eating quality of foods, potent bitter

360

taste-suppressing peptides may find additional uses as agents to reduce off-target effects of

361

certain drugs. Moreover, since the mechanism of signal transduction of T2Rs in different cell

362

types are not completely understood, peptides with inhibitory ability may be used to explore the

363

signaling pathways in different cell types. Since only one T2R was studied in this work, future

364

research works will determine the inhibitory effects of these food protein-derived hydrolysates

365

and peptides against multiple T2Rs.

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ACKNOWLEDGMENTS

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The authors are grateful for the financial support provided by Alberta Agriculture and Forestry

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funding reference number 2015P002R, Edmonton, Alberta, Canada. We acknowledge the

370

support of the Natural Sciences and Engineering Council of Canada (NSERC), funding reference

371

numbers RGPIN-249890-13 and RGPIN-2014-4099. Cette recherche a été financée par le

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Conseil de recherches en sciences naturelles et en génie du Canada (CRSNG), numéro de

373

référence RGPIN-249890-13 et RGPIN-2014-4099. We thank Appalaraju Jaggupilli for work

374

with the HEK293T-T2R4 stable cell line.

375 376 377 378 379 380 381 382 383 384 385 386 387 388 389

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Figure Captions Figure 1. Molecular weight distribution of peptides present in enzymatic beef protein hydrolysates based on elution volume from a calibrated Superdex12 10/300 GL gel permeation column. Figure 2. Estimated e-tongue bitter scores of individual beef protein hydrolysates and their ability to suppress quinine bitterness intensity. AH, alcalase hydrolysate; CH, chymotrypsin hydrolysate; PH, pepsin hydrolysate; TH, trypsin hydrolysate; TMH, thermoase hydrolysate; FH, flavourzyme hydrolysate. BCML (Nα,Nα-bis(carboxymethyl)-l-lysine) was used as a positive control. Bars with different letters have significantly different (p < 0.05) mean values. Bars labelled with uppercase or lowercase letters represent hydrolysate only or hydrolysate + quinine treatments, respectively. Figure 3. Calcium mobilization in T2R4 expressing HEK293T cell system after treatment with beef protein hydrolysates (5 mg/mL) and quinine (1 mM). AH, alcalase hydrolysate; CH, chymotrypsin hydrolysate; PH, pepsin hydrolysate; TH, trypsin hydrolysate; TMH, thermoase hydrolysate; FH, flavourzyme hydrolysate. Bars with different letters have significantly different (p < 0.05) mean values. ∆RFU: changes in relative fluorescence unit (test cells-control cells). Figure 4. Calcium mobilization in T2R4 expressing HEK293T cell system after treatment with quinine (1 mM), beef protein hydrolysate peptide fractions (5 mg/mL) or a quinine (1 mM) solution that contained 5 mg/ml protein hydrolysate peptide fractions from first round of RPHPLC separation. AH-F, alcalase hydrolysate fractions; CH-F, chymotrypsin hydrolysate fractions. Bars with different letters have significantly different (p < 0.05) mean values. Inset shows the RP-HPLC separation and fraction collection. Bars labelled with uppercase or lowercase letters represent hydrolysate only or hydrolysate + quinine treatments, respectively.

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Figure 5. Calcium mobilization in T2R4 expressing HEK293T cell system after treatment with quinine (1 mM), beef protein hydrolysate peptide fractions (5 mg/mL) or a quinine (1 mM) solution that contained 5 mg/ml alcalase hydrolysate peptide fractions (AH-F) from second round of RP-HPLC separation. Bars with different letters have significantly different (p < 0.05) mean values. Inset shows the RP-HPLC separation and fraction collection. Bars labelled with uppercase or lowercase letters represent hydrolysate only or hydrolysate + quinine treatments, respectively. Figure 6. Calcium mobilization in T2R4 expressing HEK293T cell system after treatment with quinine (1 mM), beef protein hydrolysate peptide fractions (5 mg/mL) or a quinine (1 mM) solution that contained 5 mg/ml alcalase hydrolysate peptide fractions (CH-F) from second round of RP-HPLC separation. Bars with different letters have significantly different (p < 0.05) mean values. Inset shows the RP-HPLC separation and fraction collection. Bars labelled with uppercase or lowercase letters represent hydrolysate only or hydrolysate + quinine treatments, respectively. Figure 7. Calcium mobilization in HEK293T cells stably expressing T2R4 and treated with different peptides. A. The T2R4 expressing cells were treated with quinine (1 mM), synthesized peptides (1mM) or a quinine solution that contained the synthesized peptides. The calcium responses of cells treated with buffer are used as control. Statistically significant values are shown by asterisk (*p < 0.05) and (***p < 0.001). B. Raw traces for calcium mobilization analysis showing decrease in calcium release upon stimulation with different peptides (Pep 1-8) with quinine. The black arrows at 20 sec indicates the addition of the compounds. Raw traces for both HEK293T-T2R4 stable cells and untransfected HEK293T cells are shown. The changes in fluorescence by the calcium sensitive dye Fluo-4NW are measured as relative fluorescence unit

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(∆RFU) on the Y-axis for a total of 180 seconds (X-axis) using a Flex Station 3 plate reader. Figure 8. Peptides and quinine competition calcium mobilization assay on T2R4. HEK293T cells stably expressing T2R4 were treated with 1 mM quinine and with increasing concentrations of peptides ETSARHL, AGDDAPRAVF and AAMY ranging from 0.015- 1 mM. Changes in intracellular calcium were measured (∆RFUs), and IC50 values were calculated using Graph Pad Prism 4.0. Data were collected from two-three independent experiments carried out in triplicate.

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Table 1. Degree of Hydrolysis of Enzymatic Beef Protein Hydrolysates enzyme

degree of hydrolysis (%)

Alcalase

®

35.57 ± 0.01

Chymotrypsin

®

25.83 ± 0.02

Trypsin®

24.18 ± 0.02

Pepsin®

8.60 ± 0.02

Flavourzyme® Thermoase

®

47.02 ± 0.02 18.26 ± 0.01

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Table 2. Amino Acid Composition (%) of Defatted Beef Protein (DBP) and the Enzymatic Hydrolysates* AA Asx Thr Ser

DBP 9.98 4.63 4.27

AH 10.41 4.45 4.21

CH 10.25 4.67 4.32

PH 9.99 4.26 4.13

TH TMH 10.19 10.48 4.43 4.73 4.07 4.41

FH 10.46 4.36 4.35

Mean±SD 10.23 ± 0.22 4.48 ± 0.18 4.25 ± 0.13

P-Value 0.02 0.11 0.71

Glx Pro Gly Ala Cys Val Met Ile Leu Tyr Phe His Lys Arg Trp

15.51 4.79 5.46 6.01 1.03 4.55 2.63 4.21 7.86 3.35 4.22 4.13 8.85 6.29 1.02

15.95 5.07 6.50 6.32 0.89 4.39 1.81 3.91 7.56 3.10 3.92 4.03 8.98 6.59 0.67

16.18 4.28 4.34 5.87 0.98 4.57 2.29 4.24 7.95 3.49 4.31 4.26 9.30 6.52 0.88

14.30 5.58 7.33 6.31 0.89 4.89 1.88 4.30 7.12 2.93 4.15 4.42 8.75 6.80 0.75

16.31 4.74 5.56 6.09 0.83 4.34 1.85 3.97 7.56 2.96 3.77 4.40 9.66 7.29 0.66

15.89 4.44 5.15 5.98 0.91 4.64 1.89 4.35 7.87 3.43 4.27 4.05 9.20 6.31 0.92

17.86 4.18 4.57 6.51 0.82 4.57 2.02 4.18 8.07 2.72 3.82 5.05 7.73 6.88 0.59

15.94 ± 0.90 4.72 ± 0.53 5.58 ± 1.15 6.18 ± 0.24 0.89 ± 0.06 4.57 ± 0.20 1.96 ± 0.18 4.16 ± 0.18 7.69 ± 0.35 3.11 ± 0.30 4.04 ± 0.23 4.37 ± 0.37 8.94 ± 0.67 6.72 ± 0.37 0.75 ± 0.13

0.23 0.75 0.82 0.14 0.002 0.84 0.001 0.51 0.28 0.10 0.12 0.18 0.76 0.04 0.004

HAA PCAA NCAA AAA SCAA BCAA

39.66 19.27 25.49 8.59 3.66 16.62

37.64 19.61 26.36 7.69 2.70 15.86

38.86 20.08 26.43 8.68 3.27 16.76

38.80 19.97 24.21 7.83 2.76 16.31

36.75 21.34 26.50 7.38 2.68 15.87

38.70 19.45 26.37 8.62 2.80 16.85

37.48 19.66 28.32 7.14 2.84 16.81

38.04 ± 0.87 20.02 ± 0.69 26.37 ± 1.30 7.90 ± 0.64 2.84 ± 0.22 16.41 ± 0.47

0.01 0.05 0.16 0.04 0.001 0.32

*AH, alcalase hydrolysate; CH, chymotrypsin hydrolysate; PH, pepsin hydrolysate; TH, trypsin hydrolysate; TMH, thermoase hydrolysate; FH, flavourzyme hydrolysate HAA: hydrophobic amino acids (alanine, valine, isoleucine, leucine, tyrosine, phenylalanine, tryptophan, proline, methionine and cysteine); PCAA: positively charged amino acids (histidine, lysine, arginine); NCAA: negatively charged amino acids (Asx = asparagine + aspartic acid, Glx = glutamine + glutamic acid); AAA: aromatic amino acids (phenylalanine, tryptophan, tyrosine) SCAA: Sulphur-containing amino acids (cysteine, methionine); BCAA: Branched-chain amino acid (valine, isoleucine, leucine)

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Table 3. Peptides identified from T2R4 inhibitory alcalase hydrolysate (AH) and chymotrypsin hydrolysate (CH) RP-HPLC fractions peptide Source AH-F1-3

Obs (m/z) 233.1

Z 2

suggested peptide TMTL (Pep 1)

parent protein

position

Versican core protein

f529-532

calculated mol. wt. (Da) 446.6

AH-F1-3

233.1

2

ETCL (Pep 2)

Coagulation factor XIII, B polypeptide

f1540-1545

446.5

AH-F1-3

306.2

2

SSMSSL (Pep 3)

Cardiomyopathy associated protein 1

f1540-1545

592.72

AH-F1-3

407

2

ETSARHL (Pep Myosin class II heavy chain 4)

f23-29

794.85

CH-F4-3

509

2

AGDDAPRAVF (Pep 5)

Alpha-actin-2, Alpha-actin-1, f24-33 Alpha-cardiac actin

1000.08

CH-F4-5

228.1

2

AAMY (Pep 6)

DDR2 protein FDPS protein

f368-371 f280-283

436.56

CH-F4-5

228.1

2

VSSY (Pep 7)

Desmin, Fibrillin-1 Glucagon

f20-23 f308-311 f107-110

436.43

CH-F4-5

228.1

2

AAYM (Pep 8)

KRT5 protein

f282-285

436.56

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Figure 1

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Figure 2

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Figure 3

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Absorbance at 214nm (mAU)

7,500

Chromatogram of AH in red Chromatogram of CH in black

6,000

4,500

3,000

1,500

F1 F1

0 0

6

F2 F2 12

18

F3 F3 24

F4 F4 30

36

42

48

54

60

Run time (min)

Figure 4

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Absorbance at 214nm (mAU)

1000 900 800 700 600 500 400 300 200 100 0

F1 F2 F3

F4

-100 0

6

12

18

24

30

36

42

48

Run time (min)

Figure 5

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Absorbance at 214nm (mAU)

Journal of Agricultural and Food Chemistry

1,000 900 800 700 600 500 400 300 200 100

F1 F2 F3 F4 F5 F6 F7 F8 0 0

6

12

18

24

30

36

42

48

Run time (min)

Figure 6

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A

B

Calcium mobilized (∆RFU)

300 200 100 300 200 100

A. Quinine B. Quinine+Pep 1 C. Pep 1

A

A

A. Quinine B. Quinine+Pep 4 C. Pep 4

A. Quinine B. Quinine+Pep 3 C. Pep 3

A. Quinine B. Quinine+Pep 2 C. Pep 2

A

A

B

B C

B C

C A. Quinine B. Quinine+Pep 1 C. Pep 1

A. Quinine B. Quinine+Pep 2 C. Pep 2

A

A

B

B C

B

C A. Quinine B. Quinine+Pep 4 C. Pep 4

A. Quinine B. Quinine+Pep 3 C. Pep 3

A B

HEK 293T–T2R4

HEK 293T

A B

C

C

C

30 60 90 120 30 60 90 120 30 60 90 120 30 60 90 120

Time (sec) 300 200 100 300 200 100

A. Quinine B. Quinine+Pep 6 C. Pep 6

A. Quinine B. Quinine+Pep 5 C. Pep 5

A

A

B

A

C A. Quinine B. Quinine+Pep 6 C. Pep 6

A

B

B

C

C

A

HEK 293T–T2R4

C

C A. Quinine B. Quinine+Pep 5 C. Pep 5

A. Quinine B. Quinine+Pep 8 C. Pep 8

B

B

B C

A. Quinine B. Quinine+Pep 7 C. Pep 7

A

A. Quinine B. Quinine+Pep 7 C. Pep 7 A B C

A. Quinine B. Quinine+Pep 8 C. Pep 8 A

HEK 293T

B C

30 60 90 120 30 60 90 120 30 60 90 120 30 60 90 120

Time (sec)

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Figure 8

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TOC graphic

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TOC Graphic 183x153mm (300 x 300 DPI)

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