Angiotensin I converting enzyme (ACE) inhibitory peptides from salmon byproduct protein hydrolysate by Alcalase hydrolysis

Angiotensin I converting enzyme (ACE) inhibitory peptides were produced from salmon byproduct proteins via enzymatic hydrolysis using Alcalase, flavourzyme, neutrase, pepsin, protamex and trypsin. Among them, Alcalase hydrolysate showed the highest ACE inhibitory activity, thus ACE inhibitory peptides were purified using consecutive chromatography. The purified ACE inhibitory peptides were identified to be Val-Trp-Asp-Pro-Pro-Lys-Phe-Asp (P1), Phe-Glu-Asp-Tyr-Val-Pro-Leu-Ser-Cys-Phe (P2), and Phe-Asn-Val-Pro-Leu-Tyr-Glu (P4) by time of flight-mass spectrometry/mass spectrometry (TOF-MS) analysis. The IC₅₀ values against ACE activity were 9.10 μM (P1), 10.77 μM (P2) and 7.72 μM (P4). The inhibition mode of P1, P2 and P4 was analyzed using the Lineweaver–Burk plots, demonstrating P1 to be a non-competitive inhibitor, P2 and P4 having a mixed inhibition mode. Taken together, the salmon byproduct protein hydrolysate and/or its active peptides can be used in foods for its benefits against hypertension and related diseases.     

Angiotensin I-converting enzyme inhibitory peptides in red-mold rice made by Monascus purpureus

The ACE inhibitory activity in red-mold rice extracts, prepared from 24 strains of the genus Monascus, was measured. The most effective strain for ACE inhibition was Monascus purpureus IFO 4489 (IC₅₀ = 0.71 mg/ml). Although the antihypertensive substance γ-amino butyric acid was detected in the red-mold rice (85.2 mg/kg), it did not contribute to ACE inhibition. Four ACE inhibitory peptides were isolated from the extract and identified as Ile-Tyr (IC₅₀ = 4.0 μM), Val-Val-Tyr (22.0 μM), Val-Phe (49.7 μM) and Val-Trp (3.1 μM) by protein sequencing. The ACE inhibitory activity of these peptides was almost completely preserved after successive in vitro digestion by pepsin, chymotrypsin and trypsin. These results suggest that red-mold rice made by M. purpureus could be useful in alleviating hypertension.     

Potential DPP IV Inhibitory Peptides from Dry-Cured Pork Loins after Hydrolysis: An In Vitro and In Silico Study

Peptidyl peptidase IV (DPP-IV) is a pharmacotherapeutic target in type 2 diabetes, and inhibitors of this enzyme are an important class of drugs for the treatment of type 2 diabetes. In the present study, peptides (<7 kDa) isolated from dry-cured pork loins after pepsin and pancreatin hydrolysis were identified by mass spectrometry and tested as potential inhibitors of DPP-IV by the in silico method. Two peptides, namely WTIAVPGPPHS from myomesin (water-soluble fraction, A = 0.9091) and FKRPPL from troponin (salt-soluble fraction, A = 0.8333), were selected as the most promising inhibitors of DPP-IV. Both peptides were subjected to ADMET analysis. Fragments of these peptides showed promising drug-likeness properties as well as favorable absorption, distribution, metabolism, excretion, and toxicity functions, suggesting that they are novel leads in the development of DPP-IV inhibitors from food.     

Bioactive Peptides from Bovine Milk α-Casein: Isolation,Characterization and Multifunctional properties

α-Casein group of proteins makes up to 65% of the total casein and consists of α_S1- casein_, α_S2- casein and other related proteins. Among all the proteases employed, chymotryptic peptides showed maximum inhibition for angiotensin converting enzyme (ACE). The degree of hydrolysis and release kinetics of the peptides during chymotrypsin hydrolysis was compared with biological activity and the potent peptides fractions were identified. The crude fraction obtained after 110 min of hydrolysis shows multifunctional activities, like ACE inhibition, antioxidant activity, prolyl endopeptidase inhibitory activity and antimicrobial activities. This fraction was further purified by HPLC and sequenced by mass spectra. This fraction constituted peptides with molecular weights of 1,205, 1,718 Da respectively. The sequencing of peptides by MALDI-TOF MS/MS shows sequences QKALNEINQF and TKKTKLTEEEKNRL from α-_S2 casein.     

Peptidomic Analysis of ACE Inhibitory Peptides Extracted from Fermented Goat Milk

Angiotensin converting enzyme (ACE) is considered as main causative agent in growing hypertension and other cardiovascular disorders. Inhibition of ACE by producing and purifying bioactive peptides of fermented goat milk is aimed in this study. Protein extracted from goat milk was hydrolyzed with proteolytic enzymes of LH (Lactobacillus helveticus-cicc22171). ACE inhibitory peptides were purified from fermented samples of goat milk protein by optimizing incubation time to 8 h (S-8), 16 h (S-16), 24 h (S-24) and 36 h (S-36), via ultrafiltration. S-8 was used as control to compare the ACE inhibition trend. Molecular weight cut-off; 10000 Da (PM-10) and Ultracel 3K membrane was used to perform ultrafiltration. Sample with 24 h incubation time was considered as best hydrolyzed as compared to others, by applying Nin-Hydrin reaction and SDS-PAGE analysis. ACE inhibitory assay validated the authenticity of S-24 in inhibiting ACE, in vitro. Furthermore, Q executive hybrid quadrupole-orbitrap mass spectrometry was used to determine molecular structure and amino acid sequence of ACE inhibitory peptides. Three peptides, VLPVPQKAVPQ, VLPVPQKVVPQ and TQTPVVVPPFLQPEIMGVPKVKE containing functional amino acid structure, has been identified with highest ACE inhibitory activity on the basis of intensity, size and higher concentration of hydrophobic amino acids as shown in figure as graphical abstract. Fermented goat milk containing these novel bioactive peptides, can be used as nutraceuticals to inhibit ACE and control hypertension in future.

Graphical Abstract

     

In silico identification of novel ACE and DPP-IV inhibitory peptides derived from buffalo milk proteins and evaluation of their inhibitory mechanisms

The capacity of buffalo milk proteins to release bioactive peptides was evaluated and novel bioactive peptides were identified. The sequential similarity between buffalo milk proteins and their cow counterparts was analysed. Buffalo milk proteins were simulated to yield theoretical peptides via in silico proteolysis. The potential of selected proteins to release specific bioactive peptides was evaluated by the A value obtained from the BIOPEP–UWM database (Minkiewicz et al. in Int J Mol Sci 20(23):5978, 2019). Buffalo milk protein is a suitable precursor to produce bioactive peptides, particularly dipeptidyl peptidase IV (DPP-IV) and angiotensin I-converting enzyme (ACE) inhibitory peptides. Two novel ACE inhibitory peptides (KPW and RGP) and four potential DPP-IV inhibitory peptides (RGP, KPW, FPK and KFTW) derived from in silico proteolysis of buffalo milk proteins were screened using different integrated bioinformatic approaches (PeptideRanker, Innovagen, peptide-cutter and molecular docking). The Lineweaver–Burk plots showed that KPW (IC₅₀?=?136.28?±?10.77 μM) and RGP (104.72?±?8.37 μM) acted as a competitive inhibitor against ACE. Similarly, KFTW (IC₅₀?=?873.92?±?32.89 μM) was also a competitive inhibitor of DPP-IV, while KPW and FPK (82.52?±?10.37 and 126.57?±?8.45 μM, respectively) were mixed-type inhibitors. It should be emphasized that this study does not involve any clinical trial.

     

Latent production of angiotensin I-converting enzyme inhibitors from buckwheat protein.

The latent production of angiotensin I-converting enzyme (ACE) Inhibitors from tartary buckwheat (BW) was investigated, and the peptides responsible for ACE inhibition characterized. Intact buckwheat was found to exhibit ACE inhibitory activity having an IC50 value of 3.0 mg/ml. The activity of the protein fraction (IC50: 0.36 mg protein/ml) was not enhanced by pepsin treatment. Pepsin, followed by chymotrypsin and trypsin hydrolysis, resulted in a significant increase in the ACE inhibitory activity (IC50: 0.14 mg protein/ml). The rutin contained in the buckwheat did not exhibit any ACE inhibition. A single oral administration of BW digest lowered the systolic blood pressure of a spontaneously hypertensive rat. Thus, BW proteins offer a potential resource for producing ACE inhibitory peptides during the digestion process. From the di-/tri-peptide fraction (DTPF) of the BW digest, inhibitory peptides were identified. The magnitude (%) of the total ACE inhibitory contribution of each identified peptide, relative to the overall inhibition of the DTPF, was about 41%.     

Identification and molecular docking of novel ACE inhibitory peptides from protein hydrolysates of shrimp waste

The effect of enzymatic hydrolysis by Savinase on the interfacial properties and antihypertensive activity of shrimp waste proteins was evaluated. The physicochemical characterization, interfacial tension, and surface characteristics of shrimp waste protein hydrolysates (SWPH) using different enzyme/substrate (E/S) (SWPH₅ (SWPH using E/S = 5), SWPH₁₅ (SWPH using E/S = 15), and SWPH₄₀ (SWPH using E/S = 40)) were also studied. SWPH₅, SWPH₁₅, and SWPH₄₀ had an isoelectric pH around 2.07, 2.17, and 2.54 respectively. SWPH₅ exhibited the lowest interfacial tension (68.96 mN/m) followed by SWPH₁₅ (69.36 mN/m) and SWPH₄₀ (70.29 mN/m). The in vitro ACE inhibitory activity of shrimp waste protein hydrolysates showed that the most active hydrolysate was obtained using an enzyme/substrate of 15 U/mg (SWPH₁₅). SWPH₁₅ had a lower IC₅₀ value (2.17 mg/mL) than that of SWPH₅ and SWPH₄₀ (3.65 and 5.7 mg/mL, respectively). This hydrolysate was then purified and characterized. Fraction F1 separated by Sephadex G25 column which presents the best ACE inhibition activity was then separated by reversed‐phase high performance liquid chromatography. Four ACE inhibitory peptides were identified and their molecular masses and amino acid sequences were determined using ESI–MS and ESI–MS/MS, respectively. The structures of the most potent peptides were SSSKAKKMP, HGEGGRSTHE, WLGHGGRPDHE, and WRMDIDGDIMISEQEAHQR. The structural modeling of anti‐ACE peptides from shrimp waste through docking simulations results showed that these peptides bound to ACE with high affinity.     

Preparation and characterization of novel bioactive peptides responsible for angiotensin I‐converting enzyme inhibition from wheat germ

Reported is the preparation of wheat germ (WG) hydrolyzate with potent angiotensin I‐converting enzyme (ACE) inhibitory activity, and the characterization of peptides responsible for ACE inhibition. Successful hydrolyzate with the most potent ACE inhibitory activity was obtained by 0.5 wt.%–8 h Bacillus licheniformis alkaline protease hydrolysis after 3.0 wt.%–3 h α‐amylase treatment of defatted WG (IC₅₀; 0.37 mg protein ml⁻¹). The activity of WG hydrolyzate was markedly increased by ODS and subsequent AG50W purifications (IC₅₀; 0.018 mg protein ml⁻¹). As a result of isolations by high performance liquid chromatographies, 16 peptides with the IC₅₀ value of less than 20 μm , composed of 2–7 amino acid residues were identified from the WG hydrolyzate. Judging from the high content (260 mg in 100 g of AG50W fraction) and powerful ACE inhibitory activity (IC₅₀; 0.48 μm ), Ile‐Val‐Tyr was identified as a main contributor to the ACE inhibition of the hydrolyzate. Copyright © 1999 European Peptide Society and John Wiley & Sons, Ltd.     

Purification and molecular docking study of angiotensin I-converting enzyme (ACE) inhibitory peptides from hydrolysates of marine sponge Stylotella aurantium

Angioteinsin I-converting enzyme (ACE) inhibitory peptide was isolated from marine sponge (Stylotella aurantium) hydrolysate prepared by various hydrolysis enzymes. The peptic hydrolysate exhibited highest ACE inhibitory activity among them and was fractionated into three ranges of molecular weight. The below 5 kDa fraction showed the highest ACE inhibitory activity and was used for subsequent purification steps. The amino acid sequences of the purified peptides were identified to be Tyr-Arg (337.2 Da), and Ile-Arg (287.2 Da). The purified peptides from marine sponge had an IC₅₀ value of 237.2 μM and 306.4 μM, respectively. The molecular docking study revealed that ACE inhibitory activity of the purified peptides was mainly attributed to the hydrogen bond interactions and Pi interaction between the dipeptides and ACE. The results suggest that marine sponge, S. aurantium would be an attractive raw material for the manufacture of anti-hypertensive nutraceutical ingredients.     

Conversion of Anhydride to Thiolactone in Biotin Synthesis

This study was conducted to identify the sourness-suppressing peptides in cooked pork and to clarify the mechanism of sour taste suppression by the peptides. An extract prepared from pork loins vacuum-cooked at 60 °C for 6 hours after conditioning at 4 °C for 20 days was separated into three fractions: under MW 500 (Fraction I), MW 500–1,000 (Fraction II), and over MW 1,000 (Fraction III). The Fraction I content was largest. As judged by sensory evaluation, the addition of Fraction II was capable of suppressing stronger sourness than the other fractions. Fraction II also enhanced umami and saltiness. Three peptides (APPPPAEVHEVV, APPPPAEVHEVVE, and APPPPAEVHEVHEEVH) in Fraction II increased greatly during conditioning. A common peptide, APPPPAEVHEV, in the amino acid sequences of the three peptides suppressed the sour taste. The mechanism of sourness suppression by the peptide was concluded to comprise inhibition of the binding of sour taste substances to the membranes of the tongue.     

A quantitative in silico analysis calculates the angiotensin I converting enzyme (ACE) inhibitory activity in pea and whey protein digests

Angiotensin I converting enzyme (ACE) inhibitory peptides can induce antihypertensive effects after oral administration. By means of an ACE inhibitory peptide database, containing about 500 reported sequences and their IC(50) values, the different proteins in pea and whey were quantitatively evaluated as precursors for ACE inhibitory peptides. This analysis was combined with experimental data from the evolution in ACE inhibitory activity and protein degradation during in vitro gastrointestinal digestion. Pea proteins produced similar in silico scores and were degraded early in the in vitro digestion. High ACE inhibitory activity was observed after the simulated stomach phase and augmented slightly in the simulated small intestine phase. The major whey protein beta-lactoglobulin obtained the highest in silico scores, which corresponded with the fact that degradation of this protein in vitro only occurred from the simulated small intestine phase on and resulted in a 10-fold increase in the ACE inhibitory activity. Whey protein obtained total in silico scores of about 124 ml/mg, compared to 46 ml/mg for pea protein, indicating that whey protein would be a richer source of ACE inhibitory peptides than pea protein. Although beta-lactoglobulin is only partially digested, a higher ACE inhibitory activity was indeed found in the whey (IC(50) = 0.048 mg/ml) compared to the pea digest (IC(50) = 0.076 mg/ml). In silico gastrointestinal digestion of the highest scoring proteins in pea and whey, vicilin and albumin PA2, and beta-lactoglobulin, respectively, directly released a number of potent ACE inhibitory peptides. Several other ACE inhibitory sequences resisted in silico digestion by gastrointestinal proteases. Briefly, the quantitative in silico analysis will facilitate the study of precursor proteins on a large scale and the specific release of bioactive peptides.     

Gastrointestinal enzyme production of bioactive peptides from royal jelly protein and their antihypertensive ability in SHR

In order to clarify the potential physiological function of royal jelly (RJ), we report here the gastrointestinal enzyme production of antihypertensive peptides from RJ. Intact RJ and its protein fraction did not retard the action of angiotensin I-converting enzyme (ACE) activity at all. However, development of ACE inhibition power of RJ was newly observed by pepsin hydrolysis (IC(50)=0.358 mg protein/mL), and the subsequent trypsin and chymotrypsin hydrolyses (IC(50)=0.099 mg protein/mL). Single oral administration of this gastrointestinal RJ hydrolysate (1 g/kg dose) in 10-week spontaneously hypertensive rat resulted in a significant reduction of systolic blood pressure of 22.7 plus minus 3.6 mmHg at 2 hr (P<0.05 vs. 0 hr by one-way ANOVA, n=7). Then, the RJ hydrolysate was fractionated with gel permeation chromatography to obtain the di- and tri-peptides (DTP) fraction. As a result of isolation from the DTP fraction by reversed phase-high performance liquid chromatography, eleven ACE inhibitory peptides were isolated from the DTP-RJ hydrolysate. Some of the ACE inhibitors were derived from the RJ-glycoprotein; eight peptides with the IC(50) value of <10 &mgr;M were identified from natural resources for the first time. Consequently, RJ protein was thought to be a good resource of ACE inhibitory peptides produced by the gastrointestinal enzyme hydrolyses.     

Enzyme proteolysis enhanced extraction of ACE inhibitory and antioxidant compounds (peptides and polyphenols) from Porphyra columbina residual cake

The traditional method to obtain phycocolloids from seaweeds implies successive extraction steps with cold and hot water. The residual cake derived from phycocolloids obtaining process of red seaweed Porphyra columbina is a waste containing 27 % protein and 10.7-mg gallic acid equivalents (100 g)^?1. Seaweeds contain functional proteins, and the enzymatic hydrolysis of these proteins has been shown to release bioactive peptides. The aims of this study were to extract bioactive peptides and polyphenols after enzymatic hydrolysis of the residual cake and to evaluate their ACE inhibitory and antioxidant capacities (TEAC, DPPH, and copper-chelating activity). Residual cake hydrolysate has low molecular weight peptides containing Asp, Glu, Ala, and Leu. Residual cake hydrolysate had higher protein solubility than residual cake. ACE inhibition (≈45 %) and radical scavenging activity (TEAC and DPPH inhibition) were attributed mainly to low molecular weight peptides (500 Da) and polyphenols compounds released during proteolysis. The 50 % inhibition protein concentration value (IC50) corresponded to residual cake hydrolysate was 1.01?±?0.02 and 0.91?±?0.01 g L^?1, for ABTS and DPPH, respectively. Also, residual cake hydrolysate had high copper-chelating activity (≈97.5 %). Hydrolysis could be used as a means to obtain ACE inhibitory and antioxidant compounds (peptides and polyphenols) from algae protein waste and add value to the phycocolloids extraction process.     

Characterization of new milk-derived inhibitors of angiotensin converting enzyme in vitro and in vivo

Inhibition of angiotensin converting enzyme (ACE) has been observed with a variety of different peptides, and peptide fragments with inhibitory capabilities have been identified within many different proteins, including milk proteins. The purpose of this study therefore was to identify new short peptides with inhibitory properties from the primary structure of milk proteins and to characterize them in vitro and in vivo, since no milk derived ACE inhibitors have previously been evaluated for their ability to inhibit ACE in vivo. In vitro, 8 of 9 dipeptides were found to be competitive inhibitors of ACE. The IC50 was significantly lower when an angiotensin I-like substrate was used, than when a bradykinin-like substrate was used. Using three different in vivo models for ACE inhibition, a very moderate effect was observed for three of the new peptides, but only for up to 6 or 12 minutes. Nothing was observed with two reference compounds that are reported to be hypotensive ACE-inhibitors derived from milk proteins. This raises the question whether the mechanism of hypotensive action is straightforward inhibition of ACE in vivo.     

Sourness-suppressing peptides in cooked pork loins

This study was conducted to identify the sourness-suppressing peptides in cooked pork and to clarify the mechanism of sour taste suppression by the peptides. An extract prepared from pork loins vacuum-cooked at 60 degrees C for 6 hours after conditioning at 4 degrees C for 20 days was separated into three fractions: under MW 500 (Fraction I), MW 500-1,000 (Fraction II), and over MW 1,000 (Fraction III). The Fraction I content was largest. As judged by sensory evaluation, the addition of Fraction II was capable of suppressing stronger sourness than the other fractions. Fraction II also enhanced umami and saltiness. Three peptides (APPPPAEVHEVV, APPPPAEVHEVVE, and APPPPAEVHEVHEEVH) in Fraction II increased greatly during conditioning. A common peptide, APPPPAEVHEV, in the amino acid sequences of the three peptides suppressed the sour taste. The mechanism of sourness suppression by the peptide was concluded to comprise inhibition of the binding of sour taste substances to the membranes of the tongue.     

ACE inhibitory tetrapeptides from Amaranthus hypochondriacus 11S globulin

Amaranth seed is a valuable source of dietary protein with very high nutritional quality, and recently its potential as a nutraceutical has been proposed. The aim of this work was to provide experimental evidence for the presence of anti-hypertensive peptides in globulin 11S, one of the major constituents of the seed, by means of an in-silico based peptide library screening method. A three-dimensional model of globulin 11S was built, upon which anti-hypertensive peptides were mapped via a database-driven method. Solvent accessibility was evaluated for each potential peptide, and two potent and exposed tripeptides were detected: IKP and LEP. An N-terminal extension of these two peptides was built using the globulin 11S primary sequence information, and ACE inhibitory behaviour was simulated by automated ligand-protein docking. The occurrence of two inhibitory tetrapeptides, ALEP and VIKP, was predicted and experimentally validated by an in vitro ACE inhibition assay that showed IC50 values of 6.32 mM and 175 μM, respectively. This study is the first to provide experimental proof of the anti-hypertensive value of Amaranth. Furthermore, this is the first time that a peptide docking approach is used to find ACE-inhibitory peptides from a food protein source.     

Novel antihypertensive hexa- and heptapeptides with ACE-inhibiting properties: from the in vitro ACE assay to the spontaneously hypertensive rat

Bioactive ACE inhibiting peptides are gaining interest in hypertension treatment. We have designed and screened six synthetic heptapeptides (PACEI48 to PACEI53) based on two hexapeptide leads (PACEI32 and PACEI34) to improve ACE inhibitory properties and assess their antihypertensive effects. ACE activity was assayed in vitro and ex vivo. Selected peptides were administered to spontaneously hypertensive rats (SHRs) and normotensive Wistar-Kyoto (WKY) rats. In vitro cytotoxicity was assessed with the MTT reduction test. The six heptapeptides at low micromolar concentration produced different degrees of in vitro inhibition of ACE activity using the synthetic substrate HHL or the natural substrate angiotensin I; and ex vivo inhibition of ACE-dependent, angiotensin I-induced vasoconstriction, but not angiotensin II-induced vasoconstriction. Oral administration of the hexapeptide PACEI32L, and the heptapeptides PACEI50L and PACEI52L, induced reductions in systolic blood pressure lasting up to 3 h in SHRs but not in WKY rats. Intravenous injection of PACEI32L and PACEI50L, but not PACEI52L, induced acute transient reductions in mean blood pressure of SHRs. d-Amino acid peptides showed five-fold less ACE inhibitory potency, no inhibitory effect on angiotensin I-induced vasoconstriction, and antihypertensive effect in SHRs after i.v. injection, but not after oral administration. The toxicity of peptides to reduce the viability of cultured cells was in the millimolar range. In conclusion, we have obtained novel rationally designed heptapeptides with improved ACE inhibitory properties when compared to lead hexapeptides. One selected hexapeptide and two heptapeptides show oral antihypertensive effects in SHRs and appear safe in cytotoxicity assays.     

Purification,modification and inhibition mechanism of angiotensin I-converting enzyme inhibitory peptide from silkworm pupa (Bombyx mori) protein hydrolysate

Angiotensin I-converting enzyme (ACE) inhibitory peptide from silkworm pupa (Bombyx mori) was purified, modified, as well as inhibition mechanism by using molecular docking analysis. Silkworm pupa protein was hydrolyzed by neutral protease and the obtained hydrolysate was subjected to various types of chromatography to acquire peptide isolate. Then the molecular mass and amino acid sequence of the peptide was determined by MALDI-TOF/TOF MS. Subsequently, thermal and digestive stability of the peptide were explored through a high temperature processing and a simulated gastrointestinal digestion. Finally, the peptide was modified to smaller peptides and investigated their potentiate activities. Results showed that the peptide from silkworm pupa was determined to be Gly-Asn-Pro-Trp-Met (603.7 Da) with IC₅₀ 21.70 μM. Stability testing showed that ACE inhibitory activities were not significantly changed at temperature from 40 to 80 °C as well as during in vitro gastrointestinal digestion. The inhibitory activity of four modified peptides were Trp-Trp > Gly-Asn-Pro-Trp-Trp > Asn-Pro-Trp-Trp > Pro-Trp-Trp, and the IC₅₀ of Trp-Trp was 10.76 μM Docking simulation revealed that the inhibitory activity was closely related to the spatial structure of peptide and zinc ions. The purified peptide and four modified peptides may be beneficial as functional food or drug for treating hypertension.