Scientia Agricultura Sinica ›› 2021, Vol. 54 ›› Issue (13): 2885-2894.doi: 10.3864/j.issn.0578-1752.2021.13.016

• FOOD SCIENCE AND ENGINEERING • Previous Articles     Next Articles

Preparation of Soybean Protein-Derived Pro-osteogenic Peptides via Enzymatic Hydrolysis

LI Yu1(),WANG Fang1,WENG ZeBin2,SONG HaiZhao1(),SHEN XinChun1()   

  1. 1College of Food Science and Engineering, Nanjing University of Finance and Economics/Collaborative Innovation Center for Modern Grain Circulation and Safety/Key Laboratory of Grains and Oils Quality Control and Processing, Nanjing 210023
    2College of Traditional Chinese Medicine, Nanjing University of Chinese Medicine, Nanjing 210000
  • Received:2020-10-29 Revised:2021-02-08 Online:2021-07-01 Published:2021-07-12
  • Contact: HaiZhao SONG,XinChun SHEN E-mail:18795845118@163.com;songhaizhaothu@nufe.edu.cn;shenxinchun@nufe.edu.cn

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Abstract:

【Objective】 The aim of this study was to develop an effective method and to identify the active peptides and to provide reference for the development of soybean products, so as to promote the proliferation of osteoblasts from soybean protein isolated with the two-step enzymatic hydrolysis. 【Method】The proliferative activity of osteoblast was served as an indicator. Soybean protein isolate (SPI) was hydrolyzed by papain, and the effect of papain hydrolysates on osteoblast proliferation was detected by a MTT assay. The degree of hydrolysis of the papain hydrolysates was determined by the pH-Stat method after 1, 2, 3, 4, 5 and 6 h treatment, respectively. The effects of papain hydrolysates on pro-liferation of osteoblast were determined. Two kinds of ultrafiltration membrane with 30 kDa and 10 kDa cut-off were used to separate the fractions of papain hydrolysates, and their proliferation activities on osteoblast were determined. The enzymatic hydrolysates with the highest pro-proliferative activity of osteoblast were further hydrolyzed with alkaline. The effect of alkaline enzymatic hydrolysate on the proliferation of osteoblast was examined after 0.5, 1, 1.5, 2 and 2.5 h treatment, respectively. The Sephadex G-15 was used to isolate the enzymatic hydrolysates with high pro-proliferative activity of osteoblasts, and the proliferation activity of each component on osteoblasts was determined. Furthermore, the amino acids of the separated fractions were analyzed. The structure of the most active fraction was identified by ESI-TOF MS/MS, and the soybean protein derived from peptides with strong activity to promote osteoblast proliferation was identified. 【Result】 The proliferative rate of osteoblasts was (118.24±2.73)% by the treatment with enzymatic hydrolysis products of papain for 5 h at the concentration of 200 μg/ml. After the enzymatic hydrolysates were separated by ultrafiltration membrane, the active fraction was further hydrolyzed with alkaline protease. The final hydrolysates were separated with gel filtration chromatography (Sephadex G-15). A fraction of component with the strongest pro-proliferative activity on osteoblasts, F3, was identified, and the proliferative rate of osteoblasts treated with this faction was (125.80±2.94)%. Amino acid analysis showed that the contents of hydrophobic amino acids, such as alanine, valine, isoleucine, leucine, and phenylalanine, aromatic amino acids and essential amino acids in F3, were significantly higher than other fractions. In addition, mass spectrometry (ESI-TOF MS/MS) revolved that F3 was mainly composed of 10 small peptides, among which, DAMDGWFRL, GQTPLFPR, ADFYNPK and KDWYDIK had high contents of hydrophobic amino acids, aromatic amino acids and essential amino acids. Moreover, 100 μmol∙L -1 of GQTPLFPR had the strongest pro-proliferative activity on osteoblasts, with a proliferative rate of (129.11±3.12)%.【Conclusion】 Two-step enzymatic hydrolysis combined with ultrafiltration membrane and gel filtration chromatography could identify the most active pro-proliferative peptides from SPI, which provided a technical reference for the preparation of peptides with the bio-activity to stimulate the proliferation of osteoblasts.

Key words: soybean protein isolate, osteoblast proliferation, two-step enzymatic hydrolysis, separation and purification, active peptide

Fig. 1

Effects of papain hydrolysate concentration on osteoblast proliferation * indicate significant difference (P<0.05), ** indicate extremely significant difference (P<0.01) "

Fig. 2

Relationship between time and degree of hydrolysis and effects of their papain hydrolysates on osteoblast proliferation Different letters indicate significant difference (P<0.05). The same as below "

Fig. 3

Effects of different ultrafiltration fractions on osteoblast proliferation"

Fig. 4

Effects of alcalase hydrolysate on osteoblast proliferation under different time of enzymatic hydrolysis"

Fig. 5

Chromatogram of hydrolysates separated by Sephadex G-15 (A), osteoblast proliferation of different peaks (B)"

Table 1

Amino acid composition of different fractions"

氨基酸名称
Amino acid name 		氨基酸含量 Amino acid content (g/100 g)
F1 F2 F3 F4
天冬氨酸 Aspartic acid Asp 10.20±0.66d 8.37±0.68c 4.67±0.33a 6.27±0.36b
苏氨酸 Threonine Thr 2.15±0.19a 3.69±0.23c 3.24±0.23b 2.88±0.28b
丝氨酸 Serine Ser 2.66±0.23a 5.13±0.31b 2.52±0.17a 2.58±0.24a
谷氨酸 Glutamate Glu 20.97±2.17d 14.78±0.92c 6.48±0.52a 12.06±0.69b
甘氨酸 Glycine Gly 2.64±0.23a 3.61±0.23c 3.08±0.23b 3.45±0.33c
丙氨酸 Alanine Ala 1.57±0.14a 4.58±0.28b 7.02±0.42d 5.43±0.52c
半胱氨酸 Cysteine Cys 0.52±0.05d 0.00±0.00a 0.21±0.02c 0.00±0.00a
缬氨酸 Valine Val 3.98±0.17c 3.59±0.28b 4.98±0.19d 2.51±0.24a
甲硫氨酸 Methionine Met 0.76±0.07b 0.25±0.02a 1.88±0.14e 1.56±0.16d
异亮氨酸 Isoleucine Ile 1.90±0.17c 3.91±0.23e 1.69±0.12b 0.86±0.09a
亮氨酸 Leucine Leu 5.39±0.21b 6.49±0.45c 7.58±0.50d 3.61±0.35a
酪氨酸 Tyrosine Tyr 6.43±0.43c 5.47±0.52b 13.57±0.45d 3.97±0.47a
苯丙氨 Phenylalanine Phe 6.38±0.54b 5.79±0.54b 13.06±1.14c 3.41±0.68a
赖氨酸 Lysine Lys 4.69±0.42c 4.14±0.24b 3.57±0.26a 10.34±0.55d
组氨酸 Histidine His 1.83±0.16b 1.53±0.09a 3.60±0.26c 6.77±0.64d
精氨酸 Arginine Arg 5.47±0.47b 4.65±0.28a 5.49±0.40b 7.38±0.71c
脯氨酸 Proline Pro 4.30±0.38a 5.11±0.31b 4.66±0.33a 4.73±0.45ab
疏水性氨基酸 Hydrophobic amino acid 30.71±0.31b 35.19±1.13c 54.44±1.84d 26.08±1.02a
芳香族氨基酸 Aromatic amino acid 12.81±0.29c 11.26±0.52b 26.63±0.78d 7.38±0.54a
必需氨基酸 Essential amino acid EAA 27.08±1.70a 29.39±2.10b 39.60±3.08c 31.94±2.51b

Table 2

Most abundant peptides in the F3 fraction."

序列
Sequence 		离子
Ion (m/z) 		观察质量
Observed mass 		蛋白质
Protein 		补充
Accession
KDWYDIK 484.25 (2) 967.49 40S ribosomal protein S3a OS=Glycine max OX=3847 GN=100813273 PE=2 SV=1 C6TI64
DAMDGWFRL 563.76 (2) 1126.50 Truncated Kunitz trypsin inhibitor OS=Glycine max OX=3847 PE=4 SV=1 Q9ATY0
GQTPLFPR 458.26 (2) 915.50 Uncharacterized protein OS=Glycine max OX=3847 GN=100801918 PE=3 SV=1 A0A0R0JL19
ADFYNPK 427.71 (2) 854.40 Soybean glycinin A3-B4 subunit (Fragment) OS=Glycine max OX=3847 PE=2 SV=1 Q39858
DAMDGWFR 499.22 (2) 997.42 Truncated Kunitz trypsin inhibitor OS=Glycine max OX=3847 PE=4 SV=1 Q9ATY0
NNNPFK 367.19 (2) 733.36 Uncharacterized protein OS=Glycine max OX=3847 GN=GLYMA_03G163500 PE=3 SV=1 A0A0R0KKD6
SNDVYLPR 482.25 (2) 963.49 Seed linoleate 9S-lipoxygenase-3 OS=Glycine max OX=3847 GN=LOX1.3 PE=1 SV=1 P09186
GGQLAMINLESR 435.56 (3) 1304.66 Uncharacterized protein OS=Glycine max OX=3847 GN=100796275 PE=2 SV=1 C6TKL7
DAMDGWFR 507.21 (2) 1013.41 Truncated Kunitz trypsin inhibitor OS=Glycine max OX=3847 PE=4 SV=1 Q9ATY0
THINIVVIGHVDSGK 530.29 (3) 1588.88 Elongation factor 1-alpha OS=Glycine max OX=3847 GN=100785429 PE=3 SV=1 A0A0R0ESZ8

Fig. 6

Effects of soybean active peptides DAMDGWFRL (A), GQTPLFPR (B), ADFYNPK (C) and KDWYDIK(D) on proliferation activity of osteoblast"

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