Neuromodulatory Properties of Soyabean Bioactive Proteins and Peptides

  

    
Soy Protein Source
    
Bioactive� Peptide
    
Properties
    
Tested Model
    
Reference
  
  

    
βCG
    
YVVNPDNDE N
    
Hypocholesterolemic
    
HepG2 human liver cells
    
[36,37]
  
  

    
YVVNPDNNE N
  
  

    
LAIPVNKP
    
ACE inhibition
    
In vitro ACE inhibitory activity assay
    
[12,38]
  
  

    
LPHF
  
  

    
βCG (a'-subunit)
    
Soymetide-13: MITLA IPVNKPGR
    
lmmunostimulating
    
Male ICR mice and fM LP receptor binding    assay; Phagocytosis assay;
    
[12,34,39]
  
  

    
Soymetide-9: MITLA IPVN
  
  

    
Soymetide-4:MITL
    
Anti-alopecia in neonatal rat model
    
[34 ,39-41 ]
  
  

    
KNPQLR;

      EITPEKNPQ LR; RKQEEDEDEEQQRE
    
FAS inhibitor
    
FAS inhibition studies; 3T3-L1 mouse    adipocyte
    
[16,42]
  
  

    
βCG(β-subunit) 
    
Soymorphin-5: YPFVV
    
Anti-diabetic Triglyceride-lowering    immunostimulating Suppress feeding and intestinal transit
    
Guinea pig ileum assay opioid activity;    Diabetic KKA y mice
    
[39,43-45]
  
  

    
Soymorphin-6: YPFVVN
    
Elevated Plus-Maze Test in Male ddY Mice
  
  

    
Soymorphin-7: YPFVVNA
    
Male BALB/c and ddY mice
  
  

    
VRIRLLQRFNKRS
    
Appetite supressant
    
Male BALB/c and ddY mice; Male    Sprague-Dawley rat; Mouse intestinal STC-1 cells
    
[9,39,46-48]
  
  

    
Glycinin
    
IAVPGEVA
    
Hypocholesterolemic Anti-diabetic
    
HMGR activity assay;
    
[9,39,49,50]
  
  

    
IAVPTGVA
    
HepG2 human liver cells; DPP-IV activity    assay
    
[36,50-52]
  
  

    
LPYP
    
[36,37,39,49,53]
  
  

    
VLIVP
    
ACE inhibition
    
ACE inhibitory assay
    
[12]
  
  

    
SPYP
  
  

    
WL
  
  

    
SFGVAE
    
Hypocholesterolemic
    
HMGR activity
    
[49]
  
  

    
Phagocytosis
    
HCQRPR
    
stimulatory peptide
    
Macrophages; Human polymorphonuclear    leukocytes; C3H/He mouse
    
[16,39,54]
  
  

    
QRPR
  
  

    
Glycinin (A4 and A5)
    
LPYPR
    
Hypocholesterolemic
    
Mice at dose of 50 mg/kg for 2 days; HMGR    activity assay;
    
[9,16,34,39,53]
  
  

    
NWGPLV
    
ACE inhibition
    
Spontaneously Hypertensive model rats
    
[9,12,55]
  
  

    
Lunasin
    
SKWQHQQDSCRKQKQ

      GVNLTPCEKHIMEKIQ GRGDDDDDDDDD
    
Antioxidative

      Anti-inflammatory

      Anti-cancer

      Hypocholesterolemic
    
Suppression of skin papilloma development    in

      SENCAR mice by acting as an antimitotic agent; Synergistically works with    cytokines (IL-12 or IL-2) to improve the tumoricidal activity of natural    killer cells in in vitro and in vivo tumor models;

      TEN-mediated apoptosis of MCF-7 breast cancer cells;

      Inhibits production of HMGR and increases LDLR expression;

      Antioxidant in Caco-2 cells;

      Inhibit ROS generation in HepG2 cells; Inhibit proinflammatory cascades in

      THP-1 macrophages
    
[11,12,16,29,56]
  
  

    
Bowman-Birk

      Inhibitor
    
Vglycin
    
Anti-cancer

      Proteinase inhibition Chemoprevention
    
50% reduction in the frequency of    chromosomal abnormalities and sister chromatid exchange in blood syndrome    patients; Shrink precancerous lesions in the mouth that lead to oral cancer    called leukoplakia in humans in Phase I and II clinical trials;

      Reduction in the level of serum PSA in males with benign prostatic    hyperplasia;

      Blocks the generation of ROS in prostate cancer cells (BRF-55T, 267B1/Ki-ras,    LNCaP, and PC-3 cells); protected Balb c/3T3 cells (clones A 31) exposed to

      UVC irradiation and reduced transformation;
    
[57-65]
  
  

    
Anti-diabetic
    
Normalize fasting glucose and restore    pancreatic function in Type 2 diabetic Wistar rats
    
[66]
  

Table 1: Soy bioactive peptides and their properties.

Hypolipidemic

The best studied bioactivity of soy peptides is their hypolipidemic property. Many soy peptides have been identified to lower cholesterol and triglycerides, and to suppress fat synthesis and storage in different experimental systems. LPYPR from the glycinin subunit of the soybean was one of the initial hypocholesterolemic peptides discovered by Yoshikawa et al. (2000). Administration of this peptide at a dose of 50 mg/kg of body weight without isoflavones for 2 days reduced both serum total and Low-Density Lipoprotein (LDL) cholesterol in rats by ~25% [53]. Subsequent studies further showed that, more specifically, LPYP was hypocholesterolemic [84] and acting as a competitive inhibitor of 3-Hydroxy-3-Methylglutaryl CoA Reductase (HMGR), the major rate-limiting enzyme in cholesterol biosynthesis [49]. This peptide increased LDL uptake in cultured liver cells through activating the LDL Receptor (LDLR)–Sterol Regulatory Element-Binding Protein 2 (SREBP2) pathway [36].

Two other cholesterol-lowering peptides derived from glycinin are IAVPGEVA and IAVPTGVA [50,51]. Similar to LPYP, these peptides were shown to inhibit HMGR activity in cultured HepG2 cells and promote LDL uptake via the LDLR–SREBP2 pathway [36,49]. Lammi et al. uncovered two hypocholesterolemic peptides—YVVNPDNDEN and YVVNPDNNEN—derived from soy βCG, which also modulate cholesterol by an identical mechanism [37]. Some other hypocholesterolemic soy peptides include lunasin (2S) peptides [29], SFGVAE [49], WGAPSL [12,16], LLPHH [34], RPLKPW [34], VAWWMY [85-87], and FVVNATSN [88].

Moreover, several hypotriglyceridemic di-peptides have been identified from soybean components. These are KA (from glycinin, βCG, trypsin inhibitor, and lipoxygenase), VK (from glycinin, trypsin inhibitor, and lipoxygenase), and SY (from glycinin, βCG, and lipoxygenase) [67]. βCG was shown to inhibit fatty acid synthesis in the liver leading to a reduction in serum triglycerides in rats [68]. Further studies have identified that the peptides KNPQLR, EITPEKNPQLR, and RKQEEDEDEEQQRE in this protein were able to suppress Fatty Acid Synthase (FAS) activity [16,42]. βCG subunits demonstrated a better ability to reduce lipid levels in mouse 3T3-L1 adipocytes by embedding more active peptides in the cells than glycinin subunits [89], and to suppress lipid accumulation by downregulating lipoprotein lipase and FAS [90]. Peptides ILL, LLL, and VHVV derived from Flavourzyme^®-treated soy protein isolate showed lipolysis-stimulating activity in 3T3-L1 mouse adipocytes [76,91].

Anti-Diabetic

Obesity and hyperlipidemia are often associated with insulin resistance and type II diabetes leading to the metabolic disease phenotype. Interestingly, many soy peptides with hypolipidemic function also possess anti-diabetic activity in different experimental models. For example, the hypocholesterolemic soy peptides LPYP, IAVPGEVA, and IAVPTGVA also improved glucose metabolism by increasing glucose uptake in cultured hepatic cells via Glucose Transporters (GLUT) 1 and 4 [36,92]. Further in vitro and in silico studies demonstrated that peptide IAVPTGVA was an efficient inhibitor of Dipeptidyl Peptidase IV (DPP-IV), a serine exopeptidase. DPP-IV is responsible for the hydrolysis of glucagon-like peptide and glucose-dependent insulinotropic polypeptide which are critical for maintaining glucose homeostasis [52]. Although the peptides YVVNPDNDEN and YVVNPDNNEN had similar hypocholesterolemic activity as IAVPTGVA, they were ineffective at inhibiting DPP-IV due to their longer peptide sequence and lack of Pro as the fourth N-terminal residue [52].

Both soy protein and isoflavones have been linked with improvements in diabetic rodent models [93–95] such as lowered serum glucose levels, increased insulin secretion, and reduced fasting plasma glucose. However, fermented soybean products containing soy peptides like natto and chungkookjang may be even better in the prevention of the onset of type II diabetes in human and mouse models [10,96-98]. Consumption of a diet containing soy protein (35% animal protein, 35% soy protein, and 30% other plant proteins) for 6 weeks by women aged 18–40 years (at week 24–28 of gestation) with gestational diabetes mellitus (n=34) was associated with significant improvements in fasting plasma glucose, serum insulin levels, homeostasis model of assessment—insulin resistance, and quantitative insulin sensitivity check index compared with the control diet group consisting of 70% animal and 30% plant proteins (n=34) [99]. Studies by Oliva et al. demonstrated that dyslipidemic insulin-resistant Wistar rats fed a sucrose-rich diet supplemented with soy protein had decreased hepatic triglyceride and cholesterol storage and steatosis, functional muscle glucose transporter GLUT4, and normalized glucose-6-phosphate and glycogen levels [100]. In spontaneously diabetic Goto-Kakikazi rats, consumption of βCG specifically improved muscle glucose uptake with higher plasma adiponectin, increased GLUT4 translocation, and phosphorylated Adenosine Monophosphate-Activated Protein Kinase (AMPK) [101]. Similarly, soymorphin-5 (YPFVV), a soy-derived μ-opioid peptide derived from the β-subunit of the βCG lowered glucose and triglyceride levels in diabetic KKAy mice through activation of adiponectin and Peroxisome Proliferator-Activated Receptor a (PPARa) [43]. Roblet et al. utilized electrodialysis with an ultrafiltration membrane to isolate low-molecular-weight (300–500 Da) soy peptides from a complex soy mixture [102]. This peptide fraction improved glucose uptake in cultured rat muscle cells through activation of AMPK by phosphorylation [102]. Another study showed that the soybean peptide, Vglycin, is resistant to digestive enzymes and has anti-diabetic function in type II diabetic Wistar rats [66]. Vglycin comprises 37 amino acids with 6 half-cysteines that are part of 3 pairs of disulfide bonds. When administered to diabetic Wistar rats for 4 weeks, it normalized fasting glucose levels, increased insulin sensitivity, and restored insulin signaling and pancreatic function [66].

Anti-Hypertensive

High blood pressure or hypertension is another risk factor for coronary heart disease. Interestingly, antihypertensive peptides are the most commonly occurring and best studied bioactive peptides in foods [11,16]. Antihypertensive peptides function by blocking Angiotensin-Converting Enzyme (ACE), which modulates the rennin–angiotensin system, thereby regulating blood pressure [11,34]. The dipeptidyl carboxypeptidase activity of ACE converts the decapeptide angiotensin I into the vasoconstricting octapeptide angiotensin II, resulting in increased blood pressure [11]. Traditional Asian fermented soybean foods such as soybean paste [77], soy sauce [103], natto [104], and tempeh [105] are rich in ACE inhibitory peptides [81,106]. Korean fermented soybean paste treated with chymotrypsin contains the hypotensive tripeptide, HHL [12,16], while soybean fermented with Bacillus natto or Bacillus subtilis was shown to contain two ACE inhibitor peptides, VAHINVGZK and YVWK [16,34]. Fermented soybean seasoning was shown to have a higher ACE inhibitory activity compared with soy sauce [82] and this was attributed to the peptides SY and GY, which decreased hypertension in salt-sensitive Dahl rats by suppressing the renin–angiotensin system and lowering serum aldosterone levels [83]. Okara, a soy pulp extract that is a by-product of tofu production, has been shown to have ACE inhibitory activity due to the presence of some small antihypertensive peptides [107].

The other antihypertensive soy peptides include PGTAVFK, IVF, LLF, LNF, LSW, LEF, YVVFK, IPPGVPYWT, PNNKPFQ, NWGPLV, and TPRVF [16,34]. Treatment of soy milk with the industrial protease PROTIN SD-NY10 produced FFYY, WHP, FVP, LHPGDAQR, IAV, VNP, LEPP, and WNPR peptides that had enhanced ACE inhibitory activity compared with regular soy milk [80]. In soy βCG, LAIPVNKP and LPHF were demonstrated to have ACE inhibitory activity, while glycinin was found to contain the ACE inhibitory peptides VLIVP, SPYP, and WL, and more specifically, the A4 and A5 subunits of glycinin comprised the antihypertensive peptide sequence of NWGPLV [9,12]. It has been revealed that some structural similarities exist among the bioactive peptides with blood pressure lowering properties. The presence of Pro or hydroxyl-Pro at the C-terminus made the peptides generally resistant to degradation by digestive enzymes, while Pro, Lys, or Arg were preferred at the C-terminus for ACE inhibitory potency [9,34]. It was also observed that dipeptides with a C-terminal Tyr had higher antihypertension effect than dipeptides with C-terminal Phe [9].

Anti-Cancer

Soy isoflavones have drawn much scrutiny over the years in terms of their role in cancer from both a promotion and prevention standpoint [3,6]. However, soy peptides have also been identified in different experimental systems to have anti-cancer properties [11,12,16,29,56]. Back in 2000, Kim et al. purified the hydrophobic peptide X-MLPSYSPY from defatted soy protein that arrested the cell cycle progression of murine lymphoma cells (P388D1) at G2/M phase [69]. Further studies have shown that most of the anti-cancer soy peptides belong to the minor 2S fraction of soybean proteins: lunasin and BBI [12,16,29,56–58]. The BBI is a low-molecular-weight protein, can inhibit trypsin and chymotrypsin activity, and has been considered as an anti-nutrient for a long time [57,108]. It has demonstrated anti-carcinogenicity in different species including humans and tissue types including colon, liver, esophagus, breast, prostrate, and was considered as an FDA Investigational Drug in 1992 [57,108]. In both Phases I and II human trials, the BBI promised to be a safe cancer chemopreventive agent that prevents and suppresses malignant transformation and carcinogenesis at doses from 800 to 2000 chymotrypsin inhibitor units [108,109]. The mechanism by which BBI exerts its anti-cancer activity involves apoptosis through reactive-oxygen-species-induced mitochondrial damage after proteasomal inhibition and anti-angiogenesis [110–113].

LunasinSKWQHQQDSCRKQKQGVNLTPCEKHIMEKIQGRGDDDDDDDDD) is another chemopreventive peptide that is closely associated with the BBI. It is 43 residues long with a C-terminal of 9 aspartic acid residues and cell adhesion motif, RGD that enables binding to non-acetylated H3 and H4 histones to prevent their acetylation, providing its anti-carcinogenic activity [16,34]. Park et al. showed that the BBI has a function of protecting lunasin from gastrointestinal degradation when soy protein is consumed orally [58]. Lunasin decreased skin tumor incidence in the SENCAR mice skin cancer model by ~70% when topically applied at a dose of 250 μg, and promoted colony suppression of mammalian cells induced by carcinogens and viral oncogenes E1A and RAS by 30–43% [11,12,114-117]. However, its effects on human breast cancer cell line MCF-7 appear to be inconsistent. Lunasin did not inhibit the growth rate of MCF-7 and mouse fibroblase NIH 3T3 cancer cells in vitro [117], whereas more recent study showed that lunasin induced apoptosis in MCF-7 cells by upregulation of tumor suppressor PTEN similar to the soy isoflavone genistein [56]. Lunasin is also able to inactivate the tumor suppressor proteins, Rb, p53, and pp32, and competes with the histone acetyltransferases in binding to the core deacetylated histones H3 and H4, and switching off the transcription, leading to arrest of the G1/S phase and causing apoptosis [29].

Antioxidant and Anti-Inflammatory

Carcinogenesis and cancer development depend in part on pro-inflammatory, pro-oxidant, and immunosuppressive mechanisms that lead to abnormal growth of tissue. Consequently, proteins and peptides with anti-cancer properties often also exhibit anti-inflammatory and antioxidant effects [29,70]. Soy protein with or without isoflavones was shown to reduce oxidative stress and have anti-inflammatory properties by inhibiting nuclear factor-kappa B (NF-κB) and blocking the secretion of pro-inflammatory cytokines in an oxidative-stress–inducible rat model, a hyperlipidemic mouse model, humans with end-stage renal disease, and healthy women over 70 years of age [70]. Soy milk digested with pepsin and pancreatin produced the bioactive peptides RQRK and VIK, which inhibited lipopolysaccharide-induced inflammation in murine macrophages. These hydrolysates inhibited the production of nitric oxide, Interleukin (IL)-1β, nitric oxide synthase, and cyclooxygenase-2 [79]. Lunasin’s anti-cancer potential arises from its dual anti-oxidative and anti-inflammatory capacity [29]. As an anti-oxidant, lunasin was shown to inhibit 2, 20-azino-bis (3-ethylbenzothiazoline-6sulfonic acid) diammonium salt radical scavenger, reactive oxygen species production, and the secretion of pro-inflammatory cytokines (Tumor Necrosis Factor-a and IL-6) in mouse RAW 264.7 macrophages [29,118]. It acts as a potent peroxyl and superoxide scavenger, and can prevent glutathione peroxidase and catalase activities [119]. The RGD motif of lunasin was responsible for blocking inflammation in human macrophages by interacting with aVβ3 integrin through an Akt-mediating NF-κB pathway [120]. A trial in healthy men demonstrated that ingestion of 50 g of soy protein resulted in the absorption rate of ~4.5% of the total lunasin ingested [121].

Immunomodulatory

Closely associated with anti-cancer, anti-oxidant, and anti-inflammatory peptides are immunomodulatory peptides. Immunomodulatory peptides boost immune cell functions; for example, natural killer cell activity or cytokine regulation [16]. These peptides have been found in soy protein hydrolysates that are enzymatically digested [34]. The hydrolysates prepared from insoluble soy protein with alcalase had the greatest murine splenic lymphocyte proliferation and phagocytosis capability in peritoneal macrophages [16,122]. The peptides HCGAPA and GAPA from the glycinin component of soy protein hydrolysate stimulated phagocytosis [39,54]. The trypsin digests of soy proteins revealed that the sequence MITLAIPVNKPGR was able to stimulate phagocytosis in leukocytes [34,39]. This peptide is derived from the a’-subunit of βCG and was named soymetide and later soymetide-13 since Met at its N-terminus was essential for its activity [34,39]. Some of the C-terminus residues of soymetide-13 could be removed to form soymetide-9 (MITLAIPVN) which had the highest activity. Soymetide-4 (MITL) was the minimal sequence required for its activity [39]. In general, the soymetides had an affinity for the N-formyl-methionyl-leucyl-phenylalanine receptor despite not being formylated at the N-terminus Met [39,40].

Neuromodulatory

The β-subunit of βCG contains the sequence for human β-casophormin-4 (YPFV), an opioid peptide that has morphine-like activity. This has resulted in the discovery of three peptides with anxiolytic activities: soymorphin-5 (YPFVV), soymorphin-6 (YPFVVN), and soymorphin-7 (YPFVVNA) [44]. These peptides were selective for the μ opioid receptor and were shown to suppress food intake and small intestinal transit due to the coupling of the receptor to neurotransmitters in mice [45]. In addition, soymorphin-5 was shown to improve glucose and triglyceride levels in a KKAy diabetic mouse model by activating adiponectin and PPARa, and promoting β-oxidation and energy expenditure [43]. These peptides may not need to be absorbed into the blood circulation for their anxiolytic effects. The β-subunit of βCG also contains the peptide VRIRLLQRFNKRS (fragment 51–63) which suppressed food intake and gastric emptying in rats by stimulating a mediator of satiety, plasma cholecystokinin, through an extracellular calcium-sensing receptor [46-48].

Conclusions

Soybean is a promising source of peptides that have a wide range of biological activities such as hypolipidemic, anti-diabetic, anti-hypertensive, anti-cancer, antioxidant, anti-inflammatory, immunostimulatory, and neuromodulatory properties demonstrated in different models. Further studies are warranted for better understanding of their absorption, metabolism, and target tissues, as well as for elucidating their mechanisms of actions. A high quality of human trials will help in this regard as well as address the bioavailability of the peptides. Certain functions of the soy peptides such as the anxiolytic effects of soymorphins may not require their absorption into the blood circulation. However, anti-cancer or hypolipidemic peptides need to be bioavailable to pass through the small intestines into the bloodstream to reach their target tissues. More studies are needed to identify the quantity of the active soybean peptides released by different methods (for example, in vivo or in vitro digestions), and the impact of gender and age on the action or production of bioactive soybean peptides.

References

1. Valliyodan B, Dan Q, Patil G, Zeng P, Huang J, Dai L, et al. Landscape of genomic diversity and trait discovery in soybean. Sci Rep. 2016; 6: 23598.
2. Li Y, Guan R, Liu Z, Ma Y, Wang L, Li L, et al. Genetic structure and diversity of cultivated soybean (Glycine max (L.) Merr.) landraces in China. Theor Appl Genet. 2008; 117: 857-71.
3. He FJ, Chen JQ. Consumption of soybean, soy foods, soy isoflavones and breast cancer incidence: differences between Chinese women and women in Western countries and possible mechanisms. Food Sci Hum Wellness. 2013; 2: 146-61.
4. Huang H, Krishnan HB, Pham Q, Yu LL, Wang TT. Soy and gut microbiota: interaction and implication for human health. J Agric Food Chem. 2016; 64: 8695-709.
5. Velasquez MT, Bhathena SJ. Role of dietary soy protein in obesity. Int J Med Sci. 2007; 4: 72-82.
6. Xiao CW. Health effects of soy protein and isoflavones in humans. J Nutr. 2008; 138: 1244S-9S.
7. Young VR. Soy protein in relation to human protein and amino acid nutrition. J Am Diet Assoc. 1991; 91: 828-35.
8. Omoni AO, Aluko RE. Soybean foods and their benefits: potential mechanisms of action. Nutr Rev. 2005; 63: 272-83.
9. Erdmann K, Cheung BW, Schröder H. The possible roles of food-derived bioactive peptides in reducing the risk of cardiovascular disease. J Nutr Biochem. 2008; 19: 643-54.
10. Kwon DY, Daily JW, III, Kim HJ, Park S. Antidiabetic effects of fermented soybean products on type 2 diabetes. Nutr Res. 2010; 30: 1-13.
11. Demejia EG, Delumen BO. Soybean bioactive peptides: A new horizon in preventing chronic diseases. Sex Reprod Menop. 2006; 4: 91-5.
12. Wang W, Dia VP, Vasconez M, de Mejia EG, Nelson RL. Analysis of soybean protein-derived peptides and the effect of cultivar, environmental conditions, and processing on lunasin concentration in soybean and soy products. J AOAC Int. 2008; 91: 936-46.
13. Cam A, de Mejia EG. Role of dietary proteins and peptides in cardiovascular disease. Mol Nutr Food Res. 2012; 56: 53-66.
14. Zarkadas CG, Gagnon C, Poysa V, Khanizadeh S, Cober ER, Chang V, et al. Protein quality and identification of the storage protein subunits of tofu and null soybean genotypes, using amino acid analysis, one- and two-dimensional gel electrophoresis, and tandem mass spectrometry. Food Res Int. 2007; 40: 111-28.
15. Clarke EJ, Wiseman J. Developments in plant breeding for improved nutritional quality of soya beans. I. Protein and amino acid content. J Agric Sci. 2000; 134: 111-24.
16. Singh BP, Vij S, Hati S. Functional significance of bioactive peptides derived from soybean. Peptides. 2014; 54: 171-9.
17. Poysa V, Woodrow L, Yu K. Effect of soy protein subunit composition on tofu quality. Food Res Int. 2006; 39: 309-17.
18. Maebuchi M, Samoto M, Kohno M, Ito R, Koikeda T, Hirotsuka M, et al. Improvement in the intestinal absorption of soy protein by enzymatic digestion to oligopeptide in healthy adult men. Food Sci Technol Res. 2007; 13: 45-53.
19. Kostelac D, Rechkemmer G, Briviba K. Phytoestrogens modulate binding response of estrogen receptors alpha and beta to the estrogen response element. J Agric Food Chem. 2003; 51: 7632-5.
20. Kelly LA. Phytoestrogens activate the estrogen receptor in HepG2 cells. Methods Mol Biol. 2016; 1366: 445-55.
21. Vitale DC, Piazza C, Melilli B, Drago F, Salomone S. Isoflavones: estrogenic activity, biological effect and bioavailability. Eur J Drug Metab Pharmacokinet. 2013; 38: 15-25.
22. Morito K, Hirose T, Kinjo J, Hirakawa T, Okawa M, Nohara T, et al. Interaction of phytoestrogens with estrogen receptors alpha and beta. Biol Pharm Bull. 2001; 24: 351-6.
23. Song WO, Chun OK, Hwang I, Shin HS, Kim BG, Kim KS, et al. Soy isoflavones as safe functional ingredients. J Med Food. 2007; 10: 571-80.
24. Messina M. Soy and health update: evaluation of the clinical and epidemiologic literature. Nutrients. 2016; 8: 754.
25. Zaheer K, Humayoun Akhtar M. An updated review of dietary isoflavones: nutrition, processing, bioavailability and impacts on human health. Crit Rev Food Sci Nutr. 2017; 57: 1280-93.
26. Wang Q, Ge X, Tian X, Zhang Y, Zhang J, Zhang P. Soy isoflavone: the multipurpose phytochemical (Review). Biomed Rep. 2013; 1: 697-701.
27. Cederroth CR, Nef S. Soy, phytoestrogens and metabolism: a review. Mol Cell Endocrinol. 2009; 304: 30-42.
28. Guang C, Chen J, Sang S, Cheng S. Biological functionality of soyasaponins and soyasapogenols. J Agric Food Chem. 2014; 62: 8247-55.
29. Lule VK, Garg S, Pophaly SD, Hitesh T, SK. Potential health benefits of lunation: A multifaceted soy-derived bioactive peptide. J Food Sci. 2015; 80: R485-94.
30. Aluko R, editor. Bioactive peptides. In: Functional foods and nutraceuticals. New York: Springer. 2012. p. 37-61.
31. Shahidi F, Zhong Y. Bioactive peptides. J AOAC Int. 2008; 91: 914-31.
32. De Angelis E, Pilolli R, Bavaro SL, Monaci L. Insight into the gastro-duodenal digestion resistance of soybean proteins and potential implications for residual immunogenicity. Food Funct. 2017; 8: 1599-610.
33. Korhonen H, Pihlanto-Leppäla A, Rantamäki P, Tupasela T. Impact of processing on bioactive proteins and peptides. Trends Food Sci Technol. 1998; 9: 307-19.
34. Wang W, De Mejia EG. A new frontier in soy bioactive peptides that may prevent age-related chronic diseases. Compr Rev Food Sci Food Saf. 2005; 4: 63-78.
35. Fernandez-Orozco R, Frias J, Muñoz R, Zielinski H, Piskula MK, Kozlowska H, et al. Fermentation as a bio-process to obtain functional soybean flours. J Agric Food Chem. 2007; 55: 8972-9.
36. Lammi C, Zanoni C, Arnoldi A. IAVPGEVA, IAVPTGVA, and LPYP, Three peptides from soy glycinin, modulate cholesterol metabolism in Hep G2 cells through the activation of the LDLR-SREBP2 pathway. J Funct Foods. 2015; 14: 469-78.
37. Lammi C, Zanoni C, Arnoldi A, Vistoli G. Two peptides from soy beta-Conglycinin Induce a hypocholesterolemic effect in HepG2 Cells by a statin-like mechanism: comparative in vitro and in silico modeling studies. J Agric Food Chem. 2015; 63: 7945-51.
38. Kuba M, Tana C, Tawata S, Yasuda M. Production of angiotensin I-converting enzyme inhibitory peptides from soybean protein with Monascus purpureus acid proteinase. Process Biochem. 2005; 40: 2191-6.
39. Yoshikawa M. Bioactive peptides derived from natural proteins with respect to diversity of their receptors and physiological effects. Peptides. 2015; 72: 208-25.
40. Tsuruki T, Kishi K, Takahashi M, Tanaka M, Matsukawa T, Yoshikawa M. Soymetide, an immunostimulating peptide derived from soybean beta-conglycinin, is an fMLP agonist. FEBS Lett. 2003; 540: 206-10.
41. Tsuruki T, Yoshikawa M. Design of soymetide-4 derivatives to potentiate the anti-alopecia effect. Biosci Biotechnol Biochem. 2004; 68: 1139-41.
42. Martinez-Villaluenga C, Rupasinghe SG, Schuler MA, Gonzalez de Mejia E. Peptides from purified soybean beta-conglycinin inhibit fatty acid synthase by interaction with the thioesterase catalytic domain. FEBS Journal. 2010; 277: 1481-93.
43. Yamada Y, Muraki A, Oie M, Kanegawa N, Oda A, Sawashi Y, et al. Soymorphin-5, a soy-derived mu-opioid peptide, decreases glucose and triglyceride levels through activating adiponectin and PPARalpha systems in diabetic KKAy mice. Am J Physiol Endocrinol Metab. 2012; 302: E433-40.
44. Ohinata K, Agui S, Yoshikawa M. Soymorphins, novel mu opioid peptides derived from soy beta-conglycinin beta-subunit, have anxiolytic activities. Biosci Biotechnol Biochem. 2007; 71: 2618-21.
45. Kaneko K, Iwasaki M, Yoshikawa M, Ohinata K. Orally administered soymorphins, soy-derived opioid peptides, suppress feeding and intestinal transit via gut mu(1)-receptor coupled to 5-HT(1A), D(2), and GABA(B) systems. Am J Physiol Gastrointest Liver Physiol. 2010; 299: G799-805.
46. Nishi T, Hara H, Tomita F. Soybean beta-conglycinin peptone suppresses food intake and gastric emptying by increasing plasma cholecystokinin levels in rats. J Nutr. 2003; 133: 352-7.
47. Nishi T, Hara H, Asano K, Tomita F. The soybean beta-conglycinin beta 51-63 fragment suppresses appetite by stimulating cholecystokinin release in rats. J Nutr. 2003; 133: 2537-42.
48. Nakajima S, Hira T, Eto Y, Asano K, Hara H. Soybean beta 51-63 peptide stimulates cholecystokinin secretion via a calcium-sensing receptor in enteroendocrine STC-1 cells. Regul Pept. 2010; 159: 148-55.
49. Pak VV, Koo M, Kwon DY, Yun L. Design of a highly potent inhibitory peptide acting as a competitive inhibitor of HMG-CoA reductase. Amino Acids. 2012; 43: 2015-25.
50. Pak VV, Koo MS, Kasymova TD, Kwon DY. Isolation and identification of peptides from soy 11S-globulin with hypocholesterolemic activity. Chem Nat Compd. 2005; 41: 710-4.
51. Pak VV, Koo M, Lee N, Lee JS, Kasimova TD, Kwon DY. Structure-activity relationship of Ile–Ala–Val–Pro peptide and its derivatives by using semiempirical AM1 method. Chem Nat Compd. 2005; 41: 454-60.
52. Lammi C, Zanoni C, Arnoldi A, Vistoli G. Peptides derived from soy and lupin protein as dipeptidyl-peptidase IV inhibitors: in vitro biochemical screening and in silico molecular modeling Study. J Agric Food Chem. 2016; 64: 9601-6.
53. Yoshikawa M, Fujita H, Matoba N, Takenaka Y, Yamamoto T, Yamauchi R, et al. Bioactive peptides derived from food proteins preventing lifestyle-related diseases. BioFactors. 2000; 12: 143-6.
54. Yoshikawa M, Kishi K, Takahashi M, Watanabe A, Miyamura T, Yamazaki M, et al. Immunostimulating peptide derived from soybean protein. Ann N Y Acad Sci. 1993; 685: 375-6.
55. Kodera T, Nio N. Identification of an angiotensin I-converting enzyme inhibitory peptides from protein hydrolysates by a soybean protease and the antihypertensive effects of hydrolysates in 4 spontaneously hypertensive model rats. J Food Sci. 2006; 71: C164-73.
56. Pabona JM, Dave B, Su Y, Montales MT, de Lumen BO, de Mejia EG, et al. The soybean peptide lunasin promotes apoptosis of mammary epithelial cells via induction of tumor suppressor PTEN: similarities and distinct actions from soy isoflavone genistein. Genes Nutr. 2013; 8: 79-90.
57. Losso JN. The biochemical and functional food properties of the bowman-birk inhibitor. Crit Rev Food Sci Nutr. 2008; 48: 94-118.
58. Park JH, Jeong HJ, Lumen BO. In vitro digestibility of the cancer-preventive soy peptides lunasin and BBI. J Agric Food Chem. 2007; 55: 10703-6.
59. Baturay NZ, Roque H. In vitro reduction of peroxidation in UVC-irradiated cell cultures by concurrent exposure with Bowman-Birk protease inhibitor. Teratog Carcinog Mutagen. 1991; 11: 195-202.
60. Meyskens FL. Development of difluoromethyl-ornithine and Bowman-Birk inhibitor as chemopreventive agents by assessment of relevant biomarker modulation: some lessons learned. IARC Sci Publ. 2001; 154: 49-55.
61. Kennedy AR, Radner BS, Nagasawa H. Protease inhibitors reduce the frequency of spontaneous chromosome abnormalities in cells from patients with Bloom syndrome. Proc Natl Acad Sci USA. 1984; 81: 1827-30.
62. Kennedy AR, Wan XS. Effects of the Bowman-Birk inhibitor on growth, invasion, and clonogenic survival of human prostate epithelial cells and prostate cancer cells. Prostate. 2002; 50: 125-33.
63. Malkowicz SB, McKenna WG, Vaughn DJ, Wan XS, Propert KJ, Rockwell K, et al. Effects of Bowman-Birk inhibitor concentrate (BBIC) in patients with benign prostatic hyperplasia. Prostate. 2001; 48: 16-28.
64. Armstrong WB, Kennedy AR, Wan XS, Taylor TH, Nguyen QA, Jensen J, et al. Clinical modulation of oral leukoplakia and protease activity by Bowman-Birk inhibitor concentrate in a phase IIa chemoprevention trial. Clin Cancer Res. 2000; 6: 4684-91.
65. Armstrong WB, Kennedy AR, Wan XS, Atiba J, McLaren CE, Meyskens FL, Jr. Single-dose administration of Bowman-Birk inhibitor concentrate in patients with oral leukoplakia. Cancer Epidemiol Biomarkers Prev. 2000; 9: 43-7.
66. Jiang H, Feng J, Du Z, Zhen H, Lin M, Jia S, et al. Oral administration of soybean peptide Vglycin normalizes fasting glucose and restores impaired pancreatic function in Type 2 diabetic Wistar rats. J Nutr Biochem. 2014; 25: 954-63.
67. Inoue N, Nagao K, Sakata K, Yamano N, Gunawardena PE, Han SY, et al. Screening of soy protein-derived hypotriglyceridemic di-peptides in vitro and in vivo. Lipids Health Dis. 2011; 10: 85.
68. Inoue N, Fujiwara Y, Kato M, Funayama A, Ogawa N, Tachibana N, et al. Soybean beta-conglycinin improves carbohydrate and lipid metabolism in Wistar rats. Biosci Biotechnol Biochem. 2015; 79: 1528-34.
69. Kim SE, Kim HH, Kim JY, Kang YI, Woo HJ, Lee HJ. Anticancer activity of hydrophobic peptides from soy proteins. BioFactors. 2000; 12: 151-5.
70. Draganidis D, Karagounis LG, Athanailidis I, Chatzinikolaou A, Jamurtas AZ, Fatouros IG. Inflammaging and skeletal muscle: can protein intake make a difference? J Nutr. 2016; 146: 1940-52.
71. Burris RL, Ng HP, Nagarajan S. Soy protein inhibits inflammation-induced VCAM-1 and inflammatory cytokine induction by inhibiting the NF-kappaB and AKT signaling pathway in apolipoprotein E-deficient mice. Eur J Nutr. 2014; 53: 135-48.
72. Blum A, Lang N, Peleg A, Vigder F, Israeli P, Gumanovsky M, et al. Effects of oral soy protein on markers of inflammation in postmenopausal women with mild hypercholesterolemia. Am Heart J. 2003; 145: e7.
73. Greany KA, Nettleton JA, Wangen KE, Thomas W, Kurzer MS. Consumption of isoflavone-rich soy protein does not alter homocysteine or markers of inflammation in postmenopausal women. Eur J Clin Nutr. 2008; 62: 1419-25.
74. Törmälä R, Appt S, Clarkson TB, Mueck AO, Seeger H, Mikkola TS, et al. Impact of soy supplementation on sex steroids and vascular inflammation markers in postmenopausal women using tibolone: role of equol production capability. Climacteric. 2008; 11: 409-15.
75. Gu Y, Wu J. LC-MS/MS coupled with QSAR modeling in characterising of angiotensin I-converting enzyme inhibitory peptides from soybean proteins. Food Chem. 2013; 141: 2682-90.
76. Tsou MJ, Kao FJ, Lu HC, Kao HC, Chiang WD. Purification and identification of lipolysis-stimulating peptides derived from enzymatic hydrolysis of soy protein. Food Chem. 2013; 138: 1454-60.
77. Shin ZI, Yu R, Park SA, Chung DK, Ahn CW, Nam HS, et al. His–His–Leu, an angiotensin I converting enzyme inhibitory peptide derived from Korean soybean paste, exerts antihypertensive activity in vivo. J Agric Food Chem. 2001; 49: 3004-9.
78. Kim HJ, Bae IY, Ahn CW, Lee S, Lee HG. Purification and identification of adipogenesis inhibitory peptide from black soybean protein hydrolysate. Peptides. 2007; 28: 2098-103.
79. Dia VP, Bringe NA, de Mejia EG. Peptides in pepsin-pancreatin hydrolysates from commercially available soy products that inhibit lipopolysaccharide-induced inflammation in macrophages. Food Chem. 2014; 152: 423-31.
80. Tomatsu M, Shimakage A, Shinbo M, Yamada S, Takahashi S. Novel angiotensin I-converting enzyme inhibitory peptides derived from soya milk. Food Chem. 2013; 136: 612-6.
81. Hernández-Ledesma B, Amigo L, Ramos M, Recio I. Angiotensin converting enzyme inhibitory activity in commercial fermented products. Formation of peptides under simulated gastrointestinal digestion. J Agric Food Chem. 2004; 52: 1504-10.
82. Nakahara T, Sano A, Yamaguchi H, Sugimoto K, Chikata H, Kinoshita E, et al. Antihypertensive effect of peptide-enriched soy sauce-like seasoning and identification of its angiotensin I-converting enzyme inhibitory substances. J Agric Food Chem. 2010; 58: 821-7.
83. Nakahara T, Sugimoto K, Sano A, Yamaguchi H, Katayama H, Uchida R. Antihypertensive mechanism of a peptide-enriched soy sauce-like seasoning: the active constituents and its suppressive effect on renin-angiotensin-aldosterone system. J Food Sci. 2011; 76: H201-6.
84. Kwon DY, Oh SW, Lee JS, Yang HJ, Lee SH, Lee JH, et al. Amino acid substitution of hypocholesterolemic peptides originated from glycinin hydrolyzate. Food Sci Biotechnol. 2002; 11: 55-61.
85. Choi SK, Adachi M, Utsumi S. Improved bile acid-binding ability of soybean glycinin A1a polypeptide by the introduction of a bile acid-binding peptide (VAWWMY). Biosci Biotechnol Biochem. 2004; 68: 1980-3.
86. Nagaoka S, Nakamura A, Shibata H, Kanamaru Y. Soystatin (VAWWMY), a novel bile acid-binding peptide, decreased micellar solubility and inhibited cholesterol absorption in rats. Biosci Biotechnol Biochem. 2010; 74: 1738-41.
87. Choi SK, Adachi M, Utsumi S. Identification of the bile acid-binding region in the soy glycinin A1aB1b subunit. Biosci Biotechnol Biochem. 2002; 66: 2395-401.
88. Cho SJ, Juillerat MA, Lee CH. Identification of LDL-receptor transcription stimulating peptides from soybean hydrolysate in human hepatocytes. J Agric Food Chem. 2008; 56: 4372-6.
89. Martinez-Villaluenga C, Bringe NA, Berhow MA, Gonzalez de Mejia E. Beta-conglycinin embeds active peptides that inhibit lipid accumulation in 3T3-L1 adipocytes in vitro. J Agric Food Chem. 2008; 56: 10533-43.
90. Martinez-Villaluenga C, Dia VP, Berhow M, Bringe NA, Gonzalez de Mejia E. Protein hydrolysates from beta-conglycinin enriched soybean genotypes inhibit lipid accumulation and inflammation in vitro. Mol Nutr Food Res. 2009; 53: 1007-18.
91. Tsou MJ, Lin SB, Chao CH, Chiang WD. Enhancing the lipolysis-stimulating activity of soy protein using limited hydrolysis with Flavourzyme and ultrafiltration. Food Chem. 2012; 134: 1564-70.
92. Lammi C, Zanoni C, Arnoldi A. Three peptides from soy glycinin modulate glucose metabolism in human hepatic HepG2 cells. Int J Mol Sci. 2015; 16: 27362-70.
93. Nordentoft I, Jeppesen PB, Hong J, Abudula R, Hermansen K. Increased insulin sensitivity and changes in the expression profile of key insulin regulatory genes and beta cell transcription factors in diabetic KKAy-mice after feeding with a soy bean protein rich diet high in isoflavone content. J Agric Food Chem. 2008; 56: 4377-85.
94. Lu MP, Wang R, Song X, Chibbar R, Wang X, Wu L, et al. Dietary soy isoflavones increase insulin secretion and prevent the development of diabetic cataracts in streptozotocin-induced diabetic rats. Nutr Res. 2008; 28: 464-71.
95. Cederroth CR, Vinciguerra M, Gjinovci A, Kühne F, Klein M, Cederroth M et al. Dietary phytoestrogens activate AMP-activated protein kinase with improvement in lipid and glucose metabolism. Diabetes. 2008; 57: 1176-85.
96. Taniguchi A, Yamanaka-Okumura H, Nishida Y, Yamamoto H, Taketani Y, Takeda E. Natto and viscous vegetables in a Japanese style meal suppress postprandial glucose and insulin responses. Asia Pac J Clin Nutr. 2008; 17: 663-8.
97. Fujita H, Yamagami T. Fermented soybean-derived Touchi-extract with anti-diabetic effect via alpha-glucosidase inhibitory action in a long-term administration study with KKAy mice. Life Sci. 2001; 70: 219-27.
98. Kim DJ, Jeong YJ, Kwon JH, Moon KD, Kim HJ, Jeon SM, et al. Beneficial effect of chungkukjang on regulating blood glucose and pancreatic beta-cell functions in C75BL/KsJ-db/db mice. J Med Food. 2008; 11: 215-23.
99. Jamilian M, Asemi Z. The effect of soy intake on metabolic profiles of women with gestational diabetes mellitus. J Clin Endocrinol Metab. 2015; 100: 4654-61.
100. Oliva ME, Chicco A, Lombardo YB. Mechanisms underlying the beneficial effect of soy protein in improving the metabolic abnormalities in the liver and skeletal muscle of dyslipemic insulin resistant rats. Eur J Nutr. 2015; 54: 407-19.
101. Tachibana N, Yamashita Y, Nagata M, Wanezaki S, Ashida H, Horio F, et al. Soy beta-conglycinin improves glucose uptake in skeletal muscle and ameliorates hepatic insulin resistance in Goto-Kakizaki rats. Nutr Res. 2014; 34: 160-7.
102. Roblet C, Doyen A, Amiot J, Pilon G, Marette A, Bazinet L. Enhancement of glucose uptake in muscular cell by soybean charged peptides isolated by electrodialysis with ultrafiltration membranes (EDUF): activation of the AMPK pathway. Food Chem. 2014; 147: 124-30.
103. Okamoto A, Hanagata H, Matsumoto E, Kawamura Y, Koizumi Y, Yanagida F. Angiotensin I converting enzyme inhibitory activities of various fermented foods. Biosci Biotechnol Biochem. 1995; 59: 1147-9.
104. Okamoto A, Hanagata H, Kawamura Y, Yanagida F. Anti-hypertensive substances in fermented soybean, natto. Plant Foods Hum Nutr. 1995; 47: 39-47.
105. Gibbs BF, Zougman A, Masse R, Mulligan C. Production and characterization of bioactive peptides from soy hydrolysate and soy-fermented food. Food Res Int. 2004; 37: 123-31.
106. Kuba M, Tanaka K, Tawata S, Takeda Y, Yasuda M. Angiotensin I-converting enzyme inhibitory peptides isolated from tofuyo fermented soybean food. Biosci Biotechnol Biochem. 2003; 67: 1278-83.
107. Nishibori N, Kishibuchi R, Morita K. Soy pulp extract inhibits angiotensin I-converting enzyme (ACE) Activity in vitro: evidence for its potential hypertension-improving action. J Diet Suppl. 2017; 14: 241-51.
108. Kennedy AR. The Bowman-Birk inhibitor from soybeans as an anticarcinogenic agent. Am J Clin Nutr. 1998; 68: 1406S-12S.
109. Lin LL, Mick R, Ware J, Metz J, Lustig R, Vapiwala N, et al. Phase I randomized double-blind placebo-controlled single-dose safety studies of Bowman-Birk inhibitor concentrate. Oncol Lett. 2014; 7: 1151-8.
110. Souza LC, Camargo R, Demasi M, Santana JM, de Sá CM, de Freitas SM. Effects of an anticarcinogenic Bowman-Birk protease inhibitor on purified 20S proteasome and MCF-7 breast cancer cells. PLOS ONE. 2014; 9: e86600.
111. Fereidunian A, Sadeghalvad M, Oscoie MO, Mostafaie A. Soybean Bowman-Birk protease inhibitor (BBI): identification of the mechanisms of BBI suppressive effect on growth of two adenocarcinoma cell lines: AGS and HT29. Arch Med Res. 2014; 45: 455-61.
112. Cruz-Huerta E, Fernández-Tomé S, Arques MC, Amigo L, Recio I, Clemente A, et al. The protective role of the Bowman-Birk protease inhibitor in soybean lunasin digestion: the effect of released peptides on colon cancer growth. Food Funct. 2015; 6: 2626-35.
113. Mehdad A, Brumana G, Souza AA, Barbosa J, Ventura MM, de Freitas SM. A Bowman-Birk inhibitor induces apoptosis in human breast adenocarcinoma through mitochondrial impairment and oxidative damage following proteasome 20S inhibition. Cell Death Discov. 2016; 2: 15067.
114. Galvez AF, Chen N, Macasieb J, de Lumen BO. Chemopreventive property of a soybean peptide (lunasin) that binds to deacetylated histones and inhibits acetylation. Cancer Res. 2001; 61: 7473-8.
115. Jeong HJ, Jeong JB, Kim DS, de Lumen BO. Inhibition of core histone acetylation by the cancer preventive peptide lunasin. J Agric Food Chem. 2007; 55: 632-7.
116. Jeong HJ, Park JH, Lam Y, de Lumen BO. Characterization of lunasin isolated from soybean. J Agric Food Chem. 2003; 51: 7901-6.
117. Lam Y, Galvez A, de Lumen BO. Lunasin suppresses E1A-mediated transformation of mammalian cells but does not inhibit growth of immortalized and established cancer cell lines. Nutr Cancer. 2003; 47: 88-94.
118. Hernández-Ledesma B, Hsieh CC, de Lumen BO. Antioxidant and anti-inflammatory properties of cancer preventive peptide lunasin in RAW 264.7 macrophages. Biochem Biophys Res Commun. 2009; 390: 803-8.
119. Fernández-Tomé S, Ramos S, Cordero-Herrera I, Recio I, Goya L, Hernández-Ledesma B. In vitro chemo-protective effect of bioactive peptide lunasin against oxidative stress in human HepG2 cells. Food Res Int. 2014; 62: 793-800.
120. Cam A, de Mejia EG. RGD-peptide lunation inhibits Akt-mediated NF-kappaB activation in human macrophages through interaction with the alphaVbeta3 integrin. Mol Nutr Food Res. 2012; 56: 1569-81.
121. Dia VP, Torres S, de Lumen BO, Erdman JW, de Mejia EG. Presence of lunasin in plasma of men after soy protein consumption. J Agric Food Chem. 2009; 57: 1260-6.
122. Kong X, Guo M, Hua Y, Cao D, Zhang C. Enzymatic preparation of immunomodulating hydrolysates from soy proteins. Bioresour Technol. 2008; 99: 8873-9.