Dual‐enzyme hydrolysis for preparation of ACE‐inhibitory peptides from sesame seed protein: Optimization, separation, and identification

Lü, Xin; Sun, Qiang; Zhang, Lixia; Wang, Ruidan; Gao, Jinhong; Jia, Cong; Huang, Jinian

doi:10.1111/jfbc.13638

Cited by 19 publications

(15 citation statements)

References 61 publications

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“…While Leu specificity was described by the manufacturer, Glu specificity was not. Nevertheless, this is in line with previous reports on Alc specificity (Doucet et al, 2003; Lu et al, 2021). These inconsistencies highlight a crucial aspect for successful application of the presented methodology.…”

Section: Resultssupporting

confidence: 94%

“…* References: a (García- ), b (García-Moreno, Gregersen, et al, 2020, c (Yesiltas et al, 2021), andd (García-Moreno et al, 2021). ** End of protein sequence Alc has broad specificity and has been reported to cleave after a wide range of residues (Ala/Leu/Val/Phe/Tyr/Trp/Glu/Met/Ser/Lys) with varying claims throughout literature (Doucet, Otter, Gauthier, & Foegeding, 2003;Lei, Cui, Zhao, Sun-Waterhouse, & Zhao, 2014;Lu et al, 2021;Sbroggio, Montilha, Figueiredo, Georgetti, & Kurozawa, 2016). A similar lack of consensus for Neut specificity is also found, although varying reports on the broad specificity of Alc and Neut exist, an in silico analysis based on supplier specificity (Novozymes A/S) was performed.…”

Section: 1in Silico Analysis and Design Of A Targeted Hydrolysis Processmentioning

confidence: 99%

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Targeted hydrolysis of native potato protein: A novel route for obtaining hydrolysates with improved interfacial properties

Gregersen

Jafarpour

Yeşiltaş

et al. 2022

Preprint

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Peptides and protein hydrolysates are promising alternatives to substitute chemical additives as functional food ingredients. In this study, we present a novel approach for producing a potato protein hydrolysate with improved emulsifying and foaming properties by data-driven, targeted hydrolysis. Based on previous studies, we selected 15 emulsifier peptides derived from abundant potato proteins, which were clustered based on sequence identity. Through in silico analysis, we determined that from a range of industrial proteases (Neutrase (Neut), Alcalase (Alc), Flavorzyme (Flav) and Trypsin (Tryp)), Tryp was found more likely to release peptides resembling the target peptides. After applying all proteases individually, hydrolysates were assayed for in vitro emulsifying and foaming properties. No direct correlation between degree of hydrolysis and interfacial properties was found. Tryp produced a hydrolysate (DH=5.4%) with the highest (P<0.05) emulsifying and foaming abilities, good stabilities, and high aqueous solubility. Using LC-MS/MS, we identified >10,000 peptides in each hydrolysate. Through peptide mapping, we show that random overlapping with known peptide emulsifiers is not sufficient to quantitatively describe hydrolysate functionality. While Neut hydrolysates had the highest proportion of peptides with target overlap, they showed inferior interfacial activity. In contrast, Tryp was able to release specifically targeted peptides, explaining the high surface activity observed. While modest yields and residual unhydrolyzed protein indicate room for process improvement, this work shows that data-driven, targeted hydrolysis is a viable, interdisciplinary approach to facilitate hydrolysis design for production of functional hydrolysates from alternative protein sources.

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Section: Resultssupporting

confidence: 94%

Section: 1in Silico Analysis and Design Of A Targeted Hydrolysis Processmentioning

confidence: 99%

Targeted hydrolysis of native potato protein: A novel route for obtaining hydrolysates with improved interfacial properties

Gregersen

Jafarpour

Yeşiltaş

et al. 2022

Preprint

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“…Thus, considering the production cost and e ciency, 2.5 h is selected as the central value of the time factor of the RSM. This conclusion was consistent with Xin Lu et al (Lu, 2021), who found that with the extension of time, the reaction becomes more and more su cient, and the ACE inhibition rate increases gradually, but the long-term enzymatic hydrolysis will hydrolyze the polypeptide into amino acids without ACE inhibition activity.…”

Section: Single Factor Test Of Alkaline Proteasesupporting

confidence: 90%

Preparation of angiotensin I- converting enzyme (ACE) inhibitory peptides from Tieguanyin tea residue protein using two-step enzymatic hydrolysis

LUO

Lin

et al. 2022

Preprint

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Angiotensin I-converting enzyme inhibitory (ACEI) peptides, released from precursor proteins in vitro and in vivo, have been paid increased attention in the prevention of high blood pressure. In this study, we attempted to prepare novel ACEI peptides from Tieguanyin tea residue protein (TTRP). Different proteases were used to hydrolyze TTRP to prepare ACEI peptides, neutral protease and alkaline protease hydrolysates exhibited higher ACEI activity and was chosen in further hydrolysis treatment. Response surface methodology (RSM) was used to optimize the enzymatic condition, and the results indicated that the optimal conditions of enzymatic hydrolysis were: 4% (W/V) of TTRP in water was hydrolyzed with 3500 U/g neutral protease at 50 ℃ and pH 6.5 for 2.5 h in the first step and then with 5000 U/g alkaline protease at 50 ℃ and pH 10.0 for 3 h in the second step༎Under the optimum condition, the ACE inhibitory rate of the final products was 88.45%±0.45% at the concentration of 1.0 mg/mL. Moreover, ACEI peptides derived from TTRP showed good stability under different temperatures, pHs, metal ions and gastrointestinal digestion. These results indicated that the TTRP has potential to be used for preparing ACEI peptides, providing the basis for improving the utilization efficiency for blood pressure reduction and benefit in economic value.

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“…The ACE‐inhibitory activity of LPC and LPH samples was measured using the HPLC hippuryl‐His‐Leu (HHL) substrate method described by Lu et al. (2021). The hippuric acid liberation amount from HHL was determined during the 30 min incubation at 37℃ with angiotensin I‐converting enzyme (from rabbit lung) in the presence (main sample) and absence (control) of LPC or LPH samples.…”

Section: Methodsmentioning

confidence: 99%

“…For instance, Alcalase as an endopeptidase cleaves the peptide bonds from the interior section of protein while the Flavourzyme as an endopeptidase and exopeptidase can break down the protein from interior and exterior (Xu, Galanopoulos, et al., 2020). Sequentially applying these enzymes or dual‐hydrolysis can produce peptides with higher DH or lower MWs and subsequently, amino acid composition and ACE‐inhibitory activity are altered (Lu et al., 2021). Sequential hydrolysis also has improved the bitterness of produced peptides from single hydrolysis.…”

Section: Introductionmentioning

confidence: 99%

Characterization of bioactive peptides produced from green lentil ( Lens culinaris ) seed protein concentrate using Alcalase and Flavourzyme in single and sequential hydrolysis

Rezvankhah

Yarmand

Ghanbarzadeh

et al. 2021

Food Processing Preservation

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This study aimed to produce bioactive peptides with increased angiotensin‐converting enzyme (ACE)‐inhibitory and antioxidant activities from single and sequential hydrolysis, using Alcalase and Flavourzyme at the enzyme to substrate ratio of 2% and hydrolysis time of 180 min. Results indicated that sequential hydrolysis led to a higher degree of hydrolysis (DH) value (47.05%) compared with single hydrolysis (8.51% and 20.12%). Higher ACE‐inhibitory activity and total phenol content were determined for the lentil protein hydrolysates (LPH) compared with lentil protein concentrate, and also higher antioxidant activity was obtained comparing with butylated hydroxytoluene as a synthetic antioxidant. The main amino acid profile of hydrolysates was maintained. The higher DH via hydrolysis was obtained, more small and medium molecular weight peptides were generated according to the gel permeation chromatography and sodium dodecyl sulfate–polyacrylamide gel electrophoresis. Hydrolysis did not have a significant effect on the denaturation point of protein, and thus the thermal stability was maintained. Shorter peaks were observed for hydrolysates by atomic force microscopy. Enzymatic hydrolysis increased the umami sensorial taste. Novelty impact statement Using a combination of enzymes in sequential hydrolysis can produce bioactive peptides with improved ACE‐inhibitory and antioxidant activities. Alcalase leads to the production of bitter taste peptides which can be altered by applying Flavourzyme to hydrolyze the former peptides to fewer bitter peptides. Lentil protein was hydrolyzed sequentially into bioactive peptides with improved anti‐hypertensive and antioxidant activities and increment of umami taste in respect to the produced peptides with specific amino acid profiles.

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Dual‐enzyme hydrolysis for preparation of ACE‐inhibitory peptides from sesame seed protein: Optimization, separation, and identification

Cited by 19 publications

References 61 publications

Targeted hydrolysis of native potato protein: A novel route for obtaining hydrolysates with improved interfacial properties

Targeted hydrolysis of native potato protein: A novel route for obtaining hydrolysates with improved interfacial properties

Preparation of angiotensin I- converting enzyme (ACE) inhibitory peptides from Tieguanyin tea residue protein using two-step enzymatic hydrolysis

Characterization of bioactive peptides produced from green lentil ( Lens culinaris ) seed protein concentrate using Alcalase and Flavourzyme in single and sequential hydrolysis

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