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Value - Added Products from Soybean: Removal of Anti- Nutritional Factors via Bioprocessing

Written By

Liyan Chen, Ronald L. Madl, Praveen V. Vadlani, Li Li and Weiqun Wang

Submitted: 03 April 2012 Published: 20 February 2013

DOI: 10.5772/52993

From the Edited Volume

Soybean - Bio-Active Compounds

Edited by Hany A. El-Shemy

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1. Introduction

Soybean is the second largest acreage crop in the United States (29%), right after corn (35%) according to the American Soybean Association [1]. Soybean is widely consumed in the world, particularly in Asian countries. The various soybean products could be separated into non-fermented and fermented soybean products. The non-fermented soybean products include soymilk, tofu, yuba, soybean sprouts, okara, roasted soybeans, soynuts and soy flour, immature soybeans, cooked whole soybeans, and the fermented oriental soybean products include soy paste (Jiang and Miso), soy sauce, Tempeh, Natto, soy nuggets (Douchi), sufu. In the United States, soy oil is often used for food and biodiesel production. The soybean processing process is shown in Figure 1. After the oil extraction, the residue – flaked soy meal, is usually produced into four products (textured soy flour, soy protein concentrate and soy protein isolate, 48% soy meal, soluble soy carbohydrate). The textured soy flour could be used in bakery products, meat products, infant food etc. Soy protein concentrate and isolate could be used in baby food, bakery products, cereals, lunch meat etc. SSPS (soluble soybean polysaccharides) functions as a dispersing agent, stabilizer, emulsifier, and has good adhesion properties [2]. The 48% soy meal is used for animal feed. The portions of different animal usages are poultry (48%), swine (26%), beef (12%), dairy (9%), pets (2%), others (3%) [1]. Poultry and swine usages account for74%.

Figure 1.

Soybean processing and products

The popular usage of soybean for food and feed is due to its nutritional profile. Soybean is a good protein source and the only dietary isoflavone source together with other legumes. Anti-nutritional factors in soybean, such as phytic acid, oligosaccharides, trypsin inhibitor etc, limit its usage. Fermentation with GRAS (generally recognized as safe) microorganisms has been used to help degrade these anti-nutritional factors. The nutritional value of fermented soybean and soy meal products with additional nutritional factors is then largely enhanced.

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2. Nutritional enhancement of soybean and soy meal via fermentation

2.1. Soy Protein

Protein content in soybean and soy meal are around 40%- 50% respectively. The high protein content makes soybean and soy meal a rich protein source for food and feed. As food source, the Protein Digestibility Corrected Amino Acid Score (PDCAAS), which is adopted by FDA and FAO/WHO, for isolated soy protein is 0.92, soy protein concentrate is 0.99, comparing with beef (0.92) and egg white (1.00). The human subject studies show that well-processed soy protein could serve as the sole source of protein intake for human beings [3]. FDA claims that diets containing 25 g of soy protein can reduce levels of low-density lipoproteins by as much as 10 percent and have considerable value to heart health. The specific reason for the heart protection function is unclear, for there are hundreds of protective compounds in soybean. As feed source, soy protein is high in lysine, but low in sulfur-containing amino acids, with methionine being the most limiting amino acid, followed by threonine [4]. The complementation of soy and corn for lysine and methionine makes them a valuable feed when combined.

2.1.1. Fermentation increases protein and amino acid content, and degrades protein into small functional peptides.

During fermentation, microorganisms digest the carbohydrates in soybean or soy meal and use for their own growth. The decreased dry matter and increased microorganisms weight ratio result in enhanced protein content[5-7]. In reference [5], fermented soy meal with S.cerevisae increased its protein level from 47% to 58%, while with L. plantarum and B. lactis, protein level increased to 52.08% and 52.14%. Microorganisms used for soybean fermentation have been reported to secret protease during fermentation [8-11]. In Cheonggukjang, the Bacillus subtilis fermented traditional soybean food in Korea, the acidic protease activity level could be as high as 590.24±2.92 µg/ml. Neutral protease activity level could achieve 528.13±3.11 µg/ml [9]. Because of protein degradation during fermentation, fermented soybean products are easier to digest.

Four parameters have been often used to evaluate the protein degradation of fermented soybean products. They are trichloroacetic acid (TCA) soluble nitrogen, degree of protein hydrolysis, SDS-PAGE profile, and amino acid content. Usually peptides having 10 or fewer amino acids would dissolve in TCA[12]. During fermentation, the degree of protein hydrolysis increases because of protease hydrolysis [13-14]. Meanwhile, TCA soluble nitrogen and peptide contents could also be enhanced [6, 9, 13-14]. SDS-PAGE analysis shows less large (>70 kDa) and medium (20-60 kDa) peptides and more small (<10 kDa) peptides in soy meal after fermentation of Lactobacillus plantarum, Bifidobacterium lactis, Sccharomyces cerevisiae, or Aspergillus oryzae [5, 7, 15]. Reference [13] showed that after 24 hr Bacillus subtilis fermentation, soy protein with molecular weight above 20 Kd disappeared from the electrophoretograms. The total amino acid content increased significantly (p<0.05) in fermented soy meal or soybean with Lactobacillus plantarum, Bifidobacterium lactis, Sccharomyces cerevisiae, Bacillus subtilis, Aspergillus oryzae, Rhizopus oryzae, Actinomucor elegans, Rhizopus oligosporus et al. [5, 7-8, 10-11, 13, 16]. L.plantarum fermentation of soy flour led to an increase in sulfur amino acids (Met plus Cys), Phe, Tyr, Lys, and Thr [16].

2.1.2. Functional biopeptide

Fermentation degrades large protein molecules into small peptides and amino acids. The biologically active peptides from soybean play an important role as angiotenisin converting enzyme (ACE) inhibitor [17] and as antioxidants [18]. In this section, we will discuss the ACE inhibitor. The antioxidant activity of biopeptides will be discussed in the antioxidant section.

Angiotensin I-converting enzyme (ACE, EC 3.4.15.1) is a dipeptidylcarboxypeptidase associated with the regulation of blood pressure as well as cardiovascular functions [19]. ACE-inhibitory substances are used to lower the blood pressure of hypertensive patients. Various ACE inhibitory peptides have been isolated from traditional fermented soybean foods, like natto, doujiang, soy sauce, and miso paste [20-23].

ACE inhibitory activity of peptides generated by protease is greatly dependent upon fermentation time. ACE inhibitory activity in Textured Vegetable Protein (TVP) fermented by Bacillus subtilis for 24 and 72hr showed IC50 values of 2.20 and 3.80 mg/ml, respectively [24]. The initial fermentation of TVP resulted in production of effective peptides, but longer fermentation time produced less active peptides as ACE inhibitor. Peptide with ACE inhibitory activity consisted of low molecular weight. Molecular weight of 500-1,000 Da shows the highest ACE inhibitory activity [24]. In [25], oligopeptides generated from soy hydrolysate and fermented soy foods though endoprotease digestion, demonstrated a range of biological activities – angiotensin converting enzyme (ACE) inhibitory, anti-thrombotic, surface tension and antioxidant properties.

2.1.3. Fermentation decreases soy immunoreactivity

Soybean is defined as one of the “big 8” food allergens in the United States [16].The estimated prevalence of soybean allergies is about 0.5% of the total U.S. population [16]. Patients with soy allergy could react subjectively and objectively with 0.21 and 37.2 mg of soy protein, respectively [5]. The principle for food allergy is that epitopes in allergenic protein bind to the immunoglobulin E (IgE) molecules residing in the mast cells and basophils, causing them to release inflammatory mediators, including histamine. Alpha- (72 kDa) and beta- (53 kDa) conglycinin subunits, P34 fraction, and glycinin basic (33 kDa) and acidic (22 kDa) subunits, and trypsin inhibitor (20 kDa) are the main protein components causing plasma immunoreactivity [16]. Glycine was found to stimulate local and systemic immune responses in allergic piglets and had negative effects on piglet performance [26]. The severity of the immune reactions depends on the dose of glycinin; higher doses cause more severe symptoms. The effect of purified beta-conglycinin on the growth and immune responses of rats were investigated [27]. Results showed that purified beta-conglycinin possesses intrinsic immune-stimulating capacity and can induce an allergic reaction. Also, newly weaned pigs with limited stomach acid and enzymatic secretions in the small intestine can have difficulty digesting proteins with complex structures and large molecular weights [28].

Studies have confirmed degradation of soybean allergens during fermentation by microbial proteolytic enzymes in fermented soybean products, such as soy sauce, miso and tempeh [5, 29]. In the fermented soy products, soy protein has been hydrolyzed into smaller peptides and amino acids;therefore the structure of antigen epitopes might be altered, becoming less reactive. The IgE binding potential is reduced and therefore the immunoreactivity is lowered. In soy sauce, proteins are completely degraded into peptides and amino acids after fermentation and allergens are no longer present [29]. The reduction of immunoreactivity by nature and induced fermentation of soy meal with Lactobacillus plantarum, Bifidobacterium lactis, Saccharomyces cerevisiae were evaluated [5]. S.cerevisiae, B.lactis and L. plantarum reduced the immune response77.2%, 77.2%, 78.0%, when using 97.5 kUA/l human plasma and 88.7%, 86.3%, 86.9%, respectively, when the pooled human plasma was used. All three fermented soy meal products showed fewer large (>70 kDa) and medium (20-60 kDa) peptides, and more small (<10 kDa) peptides. Protein hydrolysis reduction of soy protein immunoreactivity was also confirmed through enzyme hydrolysis conducted in reference [30], which showed that after hydrolyzing with three food-grade proteases (Alcalase, Neutrase, Corolase PN-L), no residual antigenicity was observed in resulting soy whey.

Animal experiments have also confirmed the hypoallergenic properties of fermented soybean or soy meal products. With regard to the soybean allergy, fermentation of soy meal decreased the immune response to soy protein in piglets and the level of serum IgG decreased by 27.2% [31]. Antigenic soybean proteins in the diet of early weaned pigs provoke a transient hypersensitivity associated with morphological changes including villi atrophy and crypt hyperplasia in the small intestine [31]. All of these morphological changes can cause a malabsorption syndrome [26, 33], growth depression, and diarrhea [34, 35]. Differences of the villi condition in such pigs fed soy meal and fermented soy meal were investigated by using scanning electron microscopy [36]. Piglets fed soy meal had shorter, disordered, and broader villi, whereas piglets fed fermented soy meal had long, round, regular, and tapering villi that could better digest and absorb nutrients.

2.2. Isoflavone

One of the acknowledged bioactive compounds in soybean is isolavone. Isoflavones generally exist in soybeans and soy foods as aglycones (daidzein, genistein, and glycitein), beta-glycosides (daidzin, genistin, and glycitin), acetylglycosides (6’’-O-acetyldaidzin, 6’’-O-acetylgenistin, and 6’’-O-acetylglycitin), and malonylglycosides (6’’-O-malonyldaidzin, 6’’-O—malonylgenistin, and 6’’-O-mlonylglycitin). The structures of the 12 isomers are shown in figure 2.Isoflavones physiological effects include their estrogenic activity, antioxidant and antifungal activity, and more importantly, to act as anti-carcinogens. Isoflavones may also help to reduce blood serum cholesterol levels [4].

Figure 2.

Chemical structures of 12 isoflavone isomers in soybean [4]

Among soy isoflavones, the relative abundance of genistein including respective derivatives, is the highest – about 50% of isolavone content, followed by daidzein (40%) and glycitein (10%). However, glycitein has been shown to be more bio-available than other isoflavones, followed by genistein [37]. Most of the isoflavones are associated with proteins in soy, with very little present in the lipid fraction. In their natural state, the majority of isoflavones exists as inactive glycosides (genistin, daidzin, and glycitin) and the remaining as their active aglycone forms (genistein, daidzein, and glycitein, respectively). Glycoside forms are heat sensitive, being converted into malonyl-beta-glycosylated isoflavone when heated. The aglycone forms are quite stable at high temperature [38].

Isoflavones when ingested are metabolized extensively in the intestinal tract, absorbed, transported to the liver, and undergo enterohepatic recycling. Intestinal bacterial glucosidases cleave the sugar moieties and release the biologically active isoflavones as aglycones. Aglycones could be directly absorbed in the adult and these can be further biotransformed by microorganisms to the specific metabolites, equol, desmethylangolensin, and p-ethylphenol. All of these phyto-oestrogens are then eliminated, mainly by the kidney, and therefore share the physiological features and behavior of endogenous estrogens. Among the glycones, beta-glucosides are easier to be hydrolyzed than 6’’-O-malonylglucosides and 6’’-O-acetylglucosides.

Some microorganisms have been reported to secrete beta-glucosidase, which could convert isoflavones to aglycones. The quantities of melonyl, acetyl, and glycosidyl isoflavonoids decrease during fermentation but those of isoflavonoid aglycones, daidzein, and genistein increase by over 10 to 100 fold. In Meju (long term fermented soybeans), compared with unfermented samples, the total glycosides in 60 hr fermented samples decreased from 1827 ug/g to 487 ug/g, while total aglycones increased from 22 ug/g to 329 ug/g, with daidzein increasing from trace to 152 ug/g, genistein from 16 ug/g to 170 ug/g. However, the quantity of glycitein was not increased [39]. In another study about meju fermented by Aspergillus oryzae, malonyl glycosides that initially accounted for 57.2-72.2% in the different soybeans markedly decreased to 7.4-19.9%, while aglycones originally accounted for only 1.1-2.8% in the soybeans, but markedly increased to 34.1-53.2% in miso [40]. In reference [38], total aglycones increased from 12.27 ug/g in whole soy flour to 446.90 ug/g after 48 hr fermentation by Aspergillus oryzae(ATCC 22876). Its percentage of total isoflavones increased from 2.67% to 75.51%. Daidzein content increased from trace to 133.07 ug/g, glycitein from trace to 35.56 ug/g, genistein from 12.27 ug/g to 278.27 ug/g. In Bacillus subtilis fermented soy paste ChungGuklang (CGJ), about 85% of isoflavones were in the aglycone form in the CGJ, 14% in the glucoside form and acetylglucoside and malonylglucoside forms contributed less than 1% [41]. In Bacillus pumilus HY1 fermented Cheonggkjang, the beta glucosidase increased to 24.8 U/g until 36 h. The glycosides and malonylglycosides decreased throughout the fermentation to about 80% - 90% of their starting amount at 60 hr [42]. Part of isoflavonoid aglycones are broken down into secondary metabolites, so the total quantity of isoflavonoids decreased [38, 42].

Aglycones could alleviate the symptoms of type2 diabetes, which the beta-glycosides, acetylglycosides and malonylglycosides forms are not able to do. Type 2 diabetes mellitus emerges from uncompensated peripheral insulin resistance that is associated with unregulated nutrient homeostasis, obesity, peripheral insulin resistance and progressive beta-cell failure. The effect of isoflavones in Meju on alleviating the symptoms of the type2 diabetes was investigated and four mechanismswere found [39]. Isoflavonoid aglycones could improve insulin-stimulated glucose intake. Also, they could induce PPAR-γ activation to increase insulin-stimulated glucose uptake. The PPAR-γ is the central regulator of insulin and glucose metabolism. It could help improve insulin sensitivity in type 2 diabetic patients and in diabetic rodent models. Besides, aglycones have strong effects for insulin/IGF – 1 signaling through IRS2, which plays a crucial role in beta-cell growth and survival. In this study, aglycones in meju increased GLP-1 secretion. GLP-1 is one of the incretins secreted from enteroendocrine L-cells that augments insulin secretion after the oral intake of glucose and free fatty acids. The induction of its secretion can prevent and/or relieve diabetic symptoms.

2.3. Antioxidant activity

Oxidative stress has been found to be the primary cause of many chronic diseases as well as the aging process itself. Antioxidants could help to delay or prevent oxidative stress. Epidemiological studies show that antioxidants could lower the risk of cardiovascular disease, cancer (overall risk reduction between 30 – 50%), diabetes, neurological diseases, immune diseases, eye diseases et al. [43]. Antioxidant compounds play an important role as a health protecting factor. It is beneficial to eat antioxidant enriched food. Products prepared through the fermentation of soybean including various traditional oriental fermented products of soybean such as natto, tempeh, miso and other fermented products, have been found to exhibit a significantly higher antioxidant activity than their respective non-fermented soybean substrate.

Di(phenyl)-(2,4,6-trinitrophenyl)iminoazanium(DPPH) radical scavenging activity, Fe2+ chelating activity and reducing property have been used to quantify antioxidant activity. DPPH is a stable nitrogen-centered, lipophilic free radical that is used in evaluating the antioxidant activities in a short time. Ferrous ionsare the most effective pro-oxidants in food system. Metal chelation agents prevent metal-assisted homolysis of hydroperoxides and block the formation of chain initiators. IC50 and the relative scavenging effect are the parameters to describe the DPPH radical scavenging and Fe2+ chelating abilities. IC50 is the inhibition concentration of extracts required to decrease initial DPPH radical or Fe2+ concentration by 50%. The relative scavenging effect is calculated by dividing the extract content with the IC50 of the respective extract, and then compare with the scavenging effect of control samples. The reducing property indicates that these compounds are electron donors and can reduce the oxidized intermediates, and therefore, can act as primary or secondary antioxidants. The reduction of Fe3+/ferricyanide complex to ferrous form in presence of antioxidants has been used to test the reducing activity of samples [44].

Antioxidant activity of methanol extracts of soybean koji fermented with Asp. oryzae, Asp. sojae, Actinomucor taiwanensis, Asp. awamori, and Rhizopus spp. have been investigated [44]. Methanol extracts of soybean koji, which mainly contained phenolic acid, have higher relative DPPH – scavenging effect and Fe2+ chelating effect than the unfermented steamed soybeans. The koji methanol extracts had a relative DPPH - scavenging effect of 2.3-8.9 compared with that of the non-fermented soybean, which was assigned as 1.0. Among them, the Aspergillus awamori-soybean koji exhibited the highest DPPH-scavenging effect, at a level approximately 9.0 fold than that exhibited by the non-fermented steamed soybean [44].The Fe2+ ion chelating ability of soybean increased by 2.1 – 6.7 fold after fermentation, depending on starter organism employed [44]. In Cheonggukjang fermented by Bacillus pumilus HY1, the level of DPPH radical scavenging activity increased from 54.5% to 96.2% by 60 hr [42]. In Bacillus subtilis fermented soybean kinema, when the methanol extract concentration was 50 mg/ml, 60% DPPH radical scavenging was observed. In the same product with a concentration of 10 mg/ml, the methanolic extract of kinema exhibited 64% metal chelation which was much higher than the activity shown by cooked non-fermented soybean (22%) [45]. Similar findings of enhanced reducing power of fermented bean and bean products were reported from Bacillus subtilis fermented soybean kinema[45] and from Aspergillus oryzae fermented soybean koji [44].

The enhanced antioxidant activities in fermented soybean products may be due to the increased phenolic compounds contents. Phenolic compounds have been demonstrated to exhibit a scavenging effect for free radicals and metal-chelating ability [46]. Most phenolic acids in cereals primarily occur in the bound form, as conjugates with sugars, fatty acids, or proteins [47].Isoflavones are the predominant phenolics in soybean, and the glucoside form of isoflavones represents 99% of the total isoflavones in soybean [45].This condition lowers the antioxidant activity since the availability of free hydroxyl groups in the phenolic structure is an important characteristic for the resonance stabilization of free radicals. The enhancement of bioactive phenolic compounds by enzymatic hydrolysis from different cereals was reported by Wojdylo [47] and Yuan [48]. Different enzymes during bacteria or fungi fermentation, such as alpha-amylase, alpha and beta-glucosidase, beta-glucuronidase, cellulase et al., have been reported to be involved in the lignin remobilization and phenolic compounds contents enhancement [49]. Fermented soybean products have higher amount of phenolic compounds [42, 44]. In Cheonggukjang fermented by Bacillus pumilus HY1, total phenolics increased markedly from the starting amount of 253 g/kg to 9586 g/kg at the end of fermentation (60hr) [42]. In Bacillus subtilis fermented kinema, total phenol content of kinema was 144% higher than that of cooked non-fermented soybean. The total phenol content was positively correlated (p<0.001) with radical- scavenging, reducing power, metal-chelating activity in Bacillus subtilis fermented kinema [45].

The other reason is the short chain peptides generated by fungi or bacterial protease. Antioxidant activities of peptides have been reported [50-52]. In [51], five different proteases were used to hydrolyze soybean β-conglycinin and the hydrolysates from three of them had significant enhanced antioxidative activities. Peptide antioxidant activity is related, but not limited, to the amino acid composition and its sequence. In reference [51], peptides isolated from the antioxidative beta-conglycinin hydrolysate contain histidine, proline or tyrosine residue in their sequences and hydrophobic amino acids, valine or leucine at the N terminus. The constituent amino acids had no antioxidant activity when mixed at the same concentration as the peptides. Anti-oxidative activities of peptides with different amino acid composition or sequences have different antioxidant mechanisms. Reference [52] studied the anti-oxidative properties of combinatorial tri-peptides. Tri-peptides Tyr-His-Tyr, Xaa-Xaa-Trp/Tyr, and Xaa-Xaa-Cys (SH) had a strong synergistic effect with phenolic antioxidants, a high radical scavenging activity, and a high peroxynitrite scavenging activity, respectively.

2.4. Phytic acid

Phytate is the calcium-magnesium-potassium salt of inositol hexaphosphoric acid commonly known as phytic acid [Figure 3]. Phytate and phytic acid are also referred to as phytin in some literature.

Figure 3.

Basic structure of phytic acid [52]

Phytate is the main storage form of phosphorous in soybean. Its content in soybean ranged from 1.00 to 1.47% on a dry matter basis [4].Phytate is known to be located in the protein bodies, mainly within their globoid inclusions. Phosphorous in the phytate form could not be absorbed by monogastric animals, because they lack phytase, the digestive enzyme required to release phosphorus from the phytate molecule. Phytic acid could form protein-phytate or protein-phytate-protein complexes; these have more resistance to digestion by proteolytic enzymes; thus, utilization of dietary protein is reduced. Also, phytic acid has a strong binding affinity to important minerals such as calcium, magnesium, iron, and zinc. When a mineral binds to phytic acid, it becomes insoluble, precipitates, and is not absorbable in the intestines. In food industry, the presence of phytic acid in high concentration is undesirable. In feed industry, the unabsorbed phytate passes through the gastrointestinal tract of monogastric animals, elevating the amount of phosphorus in the manure. Excess phosphorus excretion can lead to environmental problems such as eutrophication. With the pressure on the swine industry to reduce the environmental impact of pork production, it is important to use feed ingredients that can minimize this influence.

The ability of the molds for oriental fermented soybean food to produce phytase has been investigated. Phytase is the enzyme hydrolyzing phytic acid to inositol and phosphoric acid and thereby removing the metal chelating property of phytic acid. There are two strains of Rhizopus oligosporus used for tempeh fermentation, two strains of Aspergillus oryzae used for soy sauce and six strains of Aspergillus oryzae used for miso fermentation, all the ten strains were reported to be able to secret both extracellular and intracellular phytases [54]. The phytic acid content of soybeans was reduced by about one-third as a result of Rhizopus oligosporus NRRL 2710 fermentation [55-56]. That was from original 1.27% to 0.61% after 48 hr fermentation [56]. Animal test showed that fermentation of soy meal increased phosphorus availability [57-58] and zinc availability [59] and reduced phosphorus excretion without affecting growth of chicks. Using fermented soy meal as substitute for regular soy meal saved 0.2% of dietary inorganic phosphorous [60].

2.5. Oligosaccharides

Galacto-oligosacchrides (GOS) generally represent approximately 4 to 6% of soybean dry matter. In soy meal produced at 10 commercial processing plants in the United States, concentrations of stachyose, raffinose, and verbascose ranged from 41.0 to 57.2, 4.3 to 9.8, and 1.6 to 2.4 mg/g DM, respectively [61]. Oligosaccharides in the carbohydrate fraction, particularly raffinose and stachyose [figure 4], could lead to flatulence and abdominal discomfort for monogastric animals [62-63] because of the deficiency of alpha-galactosidase.

Figure 4.

Structure of raffinose and stachyose (1) raffinose; (2) stachyose

Galacto-oligosacchrides are digested to some extent in the small intestine (76 to 88% for stachyose, 31 to 65% for raffinose, and 32 to 55% for verbascose), resulting in the production of carbon dioxide and hydrogen [64]. In some cases, the accumulation of flatulent rectal gas provokes gastrointestinal distress such as abdominal pain, nausea, and diarrhea. Weanling pigs fed a GOS-free diet supplemented with 2% stachyose or fed a diet containing soy mealhad increased incidence of diarrhea compared with pigs fed a control diet [63]. Additionally, fermentation of GOS has been implicated to have negative effects on nutrient digestibilities and energy availability of soy meal. Roosters fed soy meal with low oligosaccharide concentrations had higher total net metabolizable energy values (2931 kcal/kg dm) than those fed conventional soy meal (2739 kcal/kg DM) [65]. The removal of polysaccharides from soy foods and feed is, therefore, a major factor in improving their nutritive value. To reduce non-digestible oligosaccharides, fermentation with fungi, yeast, and bacteria with alpha-galactosidase secreting ability has been attempted over the years.

The enzyme alpha-D-Gal (alpha-D-galactoside galactohydrolase, EC 3.2.1.22) is of interest for hydrolyzing the raffinose-type sugars found in soybeans. Rhizopus oligosporus, Lactobacillus curvatus R08, Leuconostoc mesenteriodes, Lactobacillus fermentum, Bifidobacterium sp. et al. have been reported to be able to produce alpha-galactosidase [56, 66-70]. These microorganisms have been applied for soybean fermentation to reduce the oligosaccharides [56, 67-68, 71]. In [56],stachyose and raffinose decreased by 56.8% and 10%, respectively, in soybean during 48 hr fermentation by Rhizopus oligosporus. In Leu.mesenteriodes JK55 and L.curvatus R08 fermented soymilk, the non-digestive oligosaccharides were completely hydrolyzed after 18-24 h of fermentation [67].

Alpha-galactosidase has been isolated from plant and microbial sources, and its properties have been documented. In general, alpha-galactosidase acts upon gal-gal bonds in the tetrasaccharide stachyose, releasing galactose and raffinose, and also acts upon gal-glu bonds with the release of sucrose. Sucrose is, in turn, split by invertase, producing fructose and glucose [72]. So, α-galatosidase activity is noticeably dependent on the type of sugar. The type and concentration of the carbon source are known to be nutritional factors that regulate the synthesis of bacterial galactosidase. Reference [67] found that the existence of glucose and fructose inhibit the alpha-galatosidase expression both in Lactobacillus curvatus R08 and Leucomostoc mesenteriodes.

2.6. Trypsin inhibitor

Protease inhibitors constitute around 6% of soybean protein [73]. Two protein protease inhibitors have been isolated from soybeans. The Kunitz trypsin inhibitor has a specificity directed primarily toward trypsin and a molecular weight of about 21.5 kDa. The Bowman-Birk (BB) inhibitor is capable of inhibiting both trypsin and chymotrypsin at independent reactive sites and has a molecular weight of 7.8 kDa [74]. Trypsin and chymotrypsin, the two major proteolytic enzymes produced in the pancreas, belong to the serine protease class.

Trypsin inhibitors present in soybeans are responsible for growth depression by reducing proteolysis and by an excessive fecal loss of pancreatic enzymes rich in sulfur-containing amino acid which can not be compensated by dietary soy protein [75]. Trypsin inhibitors account for 30-50% of the growth inhibition effect [76]. Rats fed a raw soybean extract from which trypsin inhibitors had been inactivated showed improved growth performance when compared with control rats fed diets containing raw soybeans from which inhibitors had not been inactivated [77].

Diets with a trypsin inhibitor concentration of 0.77 mg/g and less did not reduce the growth of pigs according to reference [7]. And, research showed that after fermentation with Aspergillus oryzae GB-107, the trypsin inhibitor in soy meal was reduced from 2.70 mg/g to 0.42 mg/g [7]. In the in vivo experiment of reference [15], the activities of total protease and trypsin at the duodenum and jejunum of piglets fed with fermented soy meal increased because of the inactivation of trypsin inhibitor. Just as was mentioned above, protease produced during fermentation could degrade protein molecules into peptides and amino acids. The trypsin inhibitor may be degraded or modified during fermentation and lose its activity binding to trypsin.

2.7. Vitamin

The increased content of some vitamins or provitamins, both water-soluble and fat-soluble vitamins, such as riboflavin, niacin, vitamin B6, β-carotene et al., which are due to fungal metabolic activities,is one of the healthy and nutritional advantages of fermented soybean products and has been extensively examined.

Vitamin or provitamin formation during tempeh fermentation by Rhizopus oligosporus, R.arrhizus, R. oryzae and R.slolonifer, respectively, were studied [11, 78]. In ref [11], all of the fourteen Rhizopus strains used in the research could form riboflavin, vitamin B6, nicotinic acid, nicotinamide, ergosterol, with isolates of R.oligosporus the best vitamin formers. In ref [78], six of 14 Rhizopus strains were able to form β-carotene in significant amounts. Five of these six strains belonged to the species of R.oligosporus and one was identified as R.stolonifer. A newly fourfold increase in β-carotene from 0.6 ug/g dw to 2.2 ug/g dw could be detected between 34 and 48hr in fermentations with R.oligosporus strain. During this period the content of total carotenoids increased from 9.1 ug/g dw to 11.2 ug/g dw in the fermentations with R.oligosporus strain. Ergosterol is the vitamin D2 precursor. Vitamin D can be derived from two naturally occurring compounds: ergocalciferol (D2) and cholecalciferol (D3). Both forms have equal biological activities in humans. The fourteen strains could produce ergosterol. The ergosterol concentration could be up to 1610 ug/g dw after 96 hr fermentation.

Vitamin K is an essential cofactor for the posttranslational conversion of glutamic acid residues of specific proteins in the blood and bone into γ-carboxyglutamic acid (Gla). There are two naturally occurring forms of vitamin K, vitamins K1 and K2. Vitamin K1 (phylloquinone) is formed in plants. Vitamin K2 (menaquinone, MK) is primarily synthesized by bacteria [79].Menaquinone (MK) plays an important role in blood coagulation and bone metabolism [80]. Japanese fermented soybean product, Natto, has been regarded as a high content of MK source (about 6- 9 ug/g) and is found in everyday products. Natto produced by a mutated B. subtilis strain showed a much higher content of MK up to 12.98 ug/g [81].Aromatic amino acids (phenylalanine, tyrosine, and trypstophan) could slow down the MK synthesis rate in cheonggukjang by using Bacillus amyloliquefaciens KCTC11712BP, while the supplement of 4% glycerol could signicantly increase its yield [82].

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3. Conclusion

After fermentation by GRAS microorganisms, the anti-nutritional factors in soybean or soy meal are totally degraded, including oligosaccharides, trypsin inhibitor and phytic acid. Fermentation could also degrade large soy protein into peptides and amino acids, therefore, removing the allergenic effect of soy protein. Nutritional factors are formed during fermentation along with removal of undesirable factors. Functional peptides, such as peptides with ACE inhibitory activity are created by protein degradation. Isoflavones are converted to their functional forms, the aglycones. Antioxidant activity is enhanced, contributed by the increase of short chain peptides and phenolic compounds. Certain vitamins or provitamins are formed such as riboflavin, β-carotene, vitamin K2 and ergosterol. Total nutritional profiles of soybean and soy meal are greatly enhanced by fermentation.

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Acknowledgments

The authors are grateful to the Kansas Soybean Commission and the Department of Grain, Science and Industry, Kansas State University, for funding this project. This chapteris contribution no 13-041-B from the Kansas Agricultural Experiment Station, Manhattan, KS 66506

References

  1. 1. American Soybean Association. 2012 Soy Stats http://www.soystats.com/2012 accessed 1st May 2012).
  2. 2. Maeda H. Nakamura A. 2009 Soluble soybean polysaccharide. In: Phillips GO, Williams PA. Handbook of Hydrocolloids New York: CRC Press; 693 709
  3. 3. Young V. R. 1991 Soy protein in relation to human protein and amino acid nutrition. Journal of American Dietetic Association 91 7 828 835
  4. 4. Liu K. 1997 Soybeans: Chemistry, Technology, and Utilization. New York: Chapman & Hall Press;
  5. 5. Song Y. S. Frias J. Martinez-Villaluenga C. et al. 2008 Immunoreactivity reduction of soybean meal by fermentation, effect on amino acid composition and antigenicity of commercial soy products Food Chemistry 108 571 581
  6. 6. Chen C. C. Shih Y. C. Chiou P. W. S. et al. 2010 Evaluating nutritional quality of single stage-and two stage-fermented soybean meal. Asian-Australasian Journal of Animal Science 23 5 598 606
  7. 7. Hong K. J. Lee C. H. Kim S. W. 2004 Aspergillus oryzae GB-107 Fermentation Improves Nutritional Quality of Food Soybeans and Feed Soybean Meals. Journal of Medical Food 7 4 430 435
  8. 8. Kim J. Hwang K. Lee S. 2010 ACE Inhibitory and hydrolytic enzyme activities in textured vegetable protein in relation to the solid state fermentation period using Bacillus subtilis HA Food Science and Biotechnology 19 2 487 495
  9. 9. Kim M. Han S. Ko J. Kim Y. 2012 Degradation characteristics of proteins in Cheonggukjang (fermented unsalted soybean paste) prepared with various soybean cultivars Food Science and Biotechnology 21 1 9 18
  10. 10. Omafuvbe B. O. Abiose S. H. Shonukan O. O. 2002 Fermentation of soybean (Glycine max) for soy-daddawa production by starter cultures of Bacillus. Food Microbiology 19 561 566
  11. 11. Bisping B. Hering L. Baumann U. Denter J. et al. 1993 Tempeh fermentation: some aspects of formation of γ-linolenic acid, proteases and vitamins. Biotechnology Advances 11 481 493
  12. 12. Low A. G. 1980 Nutrient absorption in pigs. Journal of the Science of Food and Agriculture 31 1087 1130
  13. 13. Weng T. Chen M. 2010 Changes of protein in Natto (a fermented soybean food) affected by fermenting time Food Science and Technology Research 16 6 537 542
  14. 14. Weng T. Chen M. 2011 Effect of two-step fermentation by Rhizopus oligosporusrus and Bacillus subtilis on protein of fermented soybean. Food Science and Technology Research 17 5 393 400
  15. 15. Feng J. Liu X. Xu Z. R. et al. 2006 The effect of Aspergillus oryzae fermented soybean meal on growth performance, digestibility of dietary components and activities of intestinal enzymes in weaned piglets. Animal Feed Science and Technology 134 295 303
  16. 16. Frias J. Song Y. S. Martinez-Villaluenga C. et al. 2008 Immunoreactivity and amino acid content of fermented soybean products. Journal of Agricultural and Food Chemistry 56 99 105
  17. 17. Zhang J. H. Tatsumi E. Ding C. H. Li L. T. 2006 Angiotensin converting enzyme inhibitory peptides in douchi, a Chinese traditional fermented soybean product. Food Chemistry 98 551 557
  18. 18. Kim S. K. Choi Y. R. Park P. J. et al. 2000 Purification and characterization of antioxidative peptides from enzymatic hydrolysate of cod teiset protein J. Korean Fish. Soc 33 198 204
  19. 19. Saxena P. R. 1992 Interaction between the renin-angiotensin-aldosterone and sympathetic nervous systems. Journal of Cardiovascular Pharmacology 19 6 8
  20. 20. Okamoto A. Hanagata H. Kawamura Y. Yanagida F. 1995 Antihypertensive substances in fermented soybean, natto. Plant Foods for Human Nutrition 47 39 47
  21. 21. Shin Z. I. Nam H. S. Lee H. J. Lee H. J. Moon T. H. 1995 Fractionation of angiotensin converting enzyme (ACE) inhibitory peptides from soybean paste. Korean Journal of Food Science and Technology 27 230 234
  22. 22. Oka S. Nagata K. 1974 Isolation and characterization of neutral peptides in soy sauce Agricultural and Biological Chemistry 38 1185 1194
  23. 23. Teranaka T. Ezawa M. Matsuyama J. Ebine H. Kiyosawa I. 1995 Inhibitory effects of extracts from rice-koji miso, barley-koji miso, and soybean-koji miso on activity of angiotensin I converting enzyme. Nippon Nogeik. Kaishi 69 1163 1169
  24. 24. Kim J. E. Hwang K. Lee S. P. 2010 ACE inhibitory and hydrolytic enzyme activities in textured vegetable protein in relation to the solid state fermentation period using Bacillus subtilis HA Food Science and Biotechnology 19 2 487 495
  25. 25. Gibbs B. F. Zougman A. Masse R. Mulligan C. 2004 Production and characterization of bioactive peptides from soy hydrolysate and soy-fermented food Food Research International 37 2 123 131
  26. 26. Sun P. Li D. F. Dong B. et al. 2008a Effects of soybean glycinin on performance and immune function in early weaned pigs. Archives of Animal Nutrition 62 313 321
  27. 27. Guo P. Piao X. Ou D. et al. 2007 Characterization of the antigenic specificity of soybean protein b-conglycinin and its effects on growth and immune function in rats. Archives of Animal Nutrition 61 3 189 200
  28. 28. Kim S. W. 2010 Bio-fermentation technology to improve efficiency of swine nutrition Asian-Australasian Journal of Animal Science 23 6 825 832
  29. 29. Kobayashi M. 2005 Immunological functions of soy sauce: hypoallergenicity and antiallergicantivity of soy sauce. Journal of Bioscience and Bioengineering 100 2 144 151
  30. 30. Penas E. Restani P. Ballabio C. et al. 2006 Assessment of the residual immunoreactivity of soybean whey hydrolysates obtained by combined enzymatic proteolysis and high pressure. European Food Research and Technology 222 286 290
  31. 31. Liu X. Feng J. Xu Z. et al. 2007 The effects of fermented soybean meal on growth performance and immune characteristics in weaned piglets Turkish Journal of Veterinary and Animal Sciences 31 5 341 345
  32. 32. Dreau D. Lalles J. P. 1999 Contribution to the study of gut hypersensitivity reactions to soybean proteins in preruminant calves and early-weaned piglets Livestock Production Science 60 209 218
  33. 33. Gu X. Li D. 2004 Effect of dietary crude protein level on villous morphology, immune status and histochemistry parameters of digestive tract in weaning piglets Animal Feed Science and Technology 114 113 126
  34. 34. Dreau D. Lalles J. P. Philouzerome V. et al. 1994 Local and systemic immune-responses to soybean protein ingestion in early-weaned pigs. Journal of Aanimal Science 72 2090 2098
  35. 35. Sun P. Li D. F. Li Z. J. et al. 2008b Effects of glycinin on IgE-mediated increase of mast cell numbers and histamine release in the small intestine The Journal of Nutritional Biochemistry 19 627 633
  36. 36. Feng J. Liu X. Xu Z. R. et al. 2007 Effect of fermented soybean meal on intestinal morphology and digestive enzyme activities in weaned piglets Digestive Diseases and Sciences 52 1845 1850
  37. 37. Masilamani M. Wei J. Sampson H. A. 2012 Regulation of the immune response by soybean isoflavones Immunologic Research in press
  38. 38. Da Silva. L. H. Celeghini R. M. S. Chang Y. K. 2011 Effect of the fermentation of whole soybean flour on the conversion of isoflavones from glycosides to aglycones. Food Chemistry 128 640 644
  39. 39. Kwon D. Y. Hong S. M. Ahn S. et al. 2011 Isoflavonoids and peptides from meju, long-term fermented soybeans, increase insulin sensitivity and exert insulinotropic effect in vitro. Nutrition 27 244 252
  40. 40. Yamabe S. Kobayashi-Hattori K. Kaneko K. Endo H. Takita T. 2007 Effect of soybean varieties on the content and composition of isoflavone in rice-koji miso Food Chemistry 100 369 374
  41. 41. Chung I. Seo S. Ahn J. et al. 2011 Effect of processing, fermentation, and aging treatment to content and profile of phenolic compounds in soybean seed, soy curd and soy paste. Food Chemistry 127 960 967
  42. 42. Cho K. M. Hong S. Y. Math R. H. Lee J. H. et al. 2009 Biotransformation of phenolics (isoflavones, flavanols and phenolic acids) during the fermentation of cheonggukjang by Bacillus pumilus HY1. Food Chemistry 114 413 419
  43. 43. Willcox J. K. Ash S. L. Catignani J. L. 2004 Antioxidants and prevention of chronic disease Critical reviews in Food Science and Nutrition 44 275 295
  44. 44. Lin C. Wei Y. Chou C. 2006 Enhanced antioxidative activity of soybean koji prepared with various filamentous fungi Food Microbiology 23 628 633
  45. 45. Moktan B. Saha J. Sarkar P. K. 2008 Antioxidant activities of soybean as affected by Bacillus-fermentation to kinema Food Research International 41 986 593
  46. 46. Shahidi F. Janitha P. K. Wanasundara P. D. 1992 Phenolic antioxidants. Critical Reviews in Food Science and Nutrition 32 67 103
  47. 47. Wojdylo A. Oszmainski J. 2007 Comparison of the content phenolic acid, alpha-tocopherol and the antioxidant activity in oat naked and weeded. Electronic Journal of Environmental, Agricultural and Food Chemistry 6 4 1980 1988
  48. 48. Yuan X. Wang J. Yao H. 2006 Production of feruloyl oligosaccharides from wheat bran insoluble dietary fibre by xylanases from Bacillus subtilis Food Chemistry 95 484 492
  49. 49. Mc Cue P. Shetty K. 2003 Role of carbohydrate-cleaving enzymes in phenolic antioxidant mobilization from whole soybean fermented with Rhizopusoligosporus. Food Biotechnology 17 1 27 37
  50. 50. Amadou I. Le Shi G. et Y. al 2011 Reducing, radical scavenging, and chelation properties of fermented soy protein meal hydrolysate by Lactobacillus plantarum LP6. International Journal of Food Properties 14 654 665
  51. 51. Chen H. Muramoto K. Yamauchi F. 1995 Structural analysis of antioxidative peptides from soybean β-conglycinin. Journal ofAgricutural and Food Chemistry 43 574 578
  52. 52. Saito K. Jin D. Ogawa T. Muramoto K. 2003 Antioxidative properties of tripeptide libraries prepared by the combinatorial chemistry. Journal of Agricultural and Food Chemistry 51 3668 3674
  53. 53. Oatway L. Vasanthan T. Helm J. H. 2001 Phytic acid Food Reviews International 17 4 419 431
  54. 54. Wang H. L. Swain E. W. Hesseltine C. W. 1980 Phytase of molds used in oriental food fermentation Journal of Food Science 45 1262 1266
  55. 55. Sudarmadji S. Markakis P. 1977 The phytate and phytase of soybean tempeh Journal of the Science of Food and Agriculture 28 381 383
  56. 56. Egounlety M. Aworth O. C. 2003 Effect of soaking, dehulling, cooking and fermentation with Rhizopus oligosporus on the oligosaccharides, trypsin inhibitor, phytic acid and tannins of soybean (Glycine max Merr.), cowpea (Vignaunguiculata L. Walp) and groundbean (Macrotyloma geocarpa) Harm Journal of food engineering 56 249 254
  57. 57. Kim S. S. Galaz G. B. MA Pham et. al 2009 Effects of dietary supplementation of a meju, fermented soybean meal, and Aspergillus oryzae for Juvenile Parrot Fish (Oplegnathusfasciatus). Asian-Australasian Journal of Animal Science 22 6 849 856
  58. 58. Matsui T. Hirabayashi M. Iwama Y. et al. 1996 Fermentation of soya-bean meal with Aspergillus usami improves phosphorus availability in chicks. Animal Feed Science and Technology 60 1-2 131 136
  59. 59. Hirabayashi M. Matsui T. Yano H. 1998a Fermentation of soybean meal with Aspergillus usami improves zinc availability in rats. Biological Trace Element Research 61 2 227 234
  60. 60. Hirabayashi M. Matsui T. Yano H. et al. 1998b Fermentation of soybean meal with Aspergillususamii reduces phosphorus excretion in chicks. Poultry Science 77 552 556
  61. 61. Grieshop C. M. Kadzere C. T. Clapper G. M. et al. 2003 Chemical and nutritional characteristics of United States soybeans and soybean meals. Journal of Agricultural and Food Chemistry 51 7684 7691
  62. 62. Krause D. O. Easter R. A. Mackie R. I. 1994 Fermentation of stachyose and raffinose by hindgut bacteria of the weanling pig. Letters in Applied Microbiology 18 349 352
  63. 63. Zhang L. Y. Li D. F. Qiao S. Y. et al. 2003 Effects of stachyose on performance, diarrhoea incidence and intestinal bacteria in weanling pigs Archives of Animal Nutrition 57 1 10
  64. 64. Karr-Lilienthal L. K. Kadzere C. T. Grieshop C. M. et al. 2005 Chemical and nutritional properties of soybean carbohydrates as related to nonruminants: a review Livestock Production Science 97 1 12
  65. 65. Parsons C. M. Yhang Y. Araba M. 2000 Nutritional evaluation of soybean meals varying in oligosaccharides content. Poultry Science 79 1127 1131
  66. 66. Nout M. J. R. Rombouts F. M. 1990 Recent developments in tempeh research. Journal of Applied Bacteriology 69 5 609 633
  67. 67. Yoon M. Y. Hwang H. 2008 Reduction of soybean oligosaccharides and properties of alpha-D-galactosidase from Lactobacillus curvatus R08 and Leuconostoc mesenteriodes JK55. Food Microbiology 25 815 823
  68. 68. Wang Y. C. Yu R. C. Yang H. Y. Chou C. C. 2002 Growth and survival of bifidobacteria and lactic acid bacteria during the fermentation and storage of cultured soymilk drinks Food Microbiology 19 501 508
  69. 69. Garro M. S. de Valdez G. F. Oliver G. de Giori G. S. 1996 Purification of alpha-galactosidase from Lactobacilus ferment. Journal of Biotechnology 45 103 109
  70. 70. Leblanc J. G. MS Garro de Giori. G. S. 2004a Effect of pH on Lactobacillus fermentum growth, raffinose removal, alpha-galactosidase activity and fermentation products Applied Microbiology and Biotechnology 65 119 123
  71. 71. Le Blanc J. G. MS Garro Silvestroni. A. Connes C. Piard J. C. Sesma F. de Giori G. S. 2004b Reduction of alpha-galactooligosaccharides in soyamilk by Latobacillusfermentum CRL 722: in vitro and in vivo evaluation of fermented soyamilk. Journal of Applied Microbiology 97 876 881
  72. 72. Mulimani V. H. Thippeswamy S. Ramalingam S. 1997 Enzymatic degradation of oligosaccharides in soybean flour. Food Chemistry 59 279 282
  73. 73. Friedman M. Brandon D. L. Nutritional and health benefits of soy proteins. Journal of Agricultural and Food Chemistry 2001 49 3 1069 1086
  74. 74. Hocine L. L. Boye J. I. 2007 Allergenicity of soybean: new developments in identification of allergenic proteins, cross-reactivities and hypoallergenization technologies. Critical Reviews in Food Science and Nutrition 47 127 143
  75. 75. Rackis J. J. 1981 Gumbmann MR. Protease inhibitors: physiological properties and nutritional significance. In: Ory RL. (ed.) Antinutrrents and natural toxicants in foods. USA: Food & Nutrition Press Inc; 203 237
  76. 76. Isanga J. Zhang G. 2008 Soybean bioactive components and their implications to health- a review. Food reviews International 24 252 276
  77. 77. Kakade M. L. Hoffa D. E. Liener I. E. 1973 Contribution of trypsin inhibitors to the deleterious effects of unheated soybeans fed to rats. Journal of Nutrition 103 1172
  78. 78. Denter J. Rehm H. Bisping B. 1998 Changes in the contents of fat-soluble vitamins and provitamins during tempeh fermentation. International Journal of Food Microbiology 45 129 134
  79. 79. Sato T. Yamada Y. Ohtani Y. et al. 200 2001 Production of Menaquinone (Vitamine K2)- 7 by Bacillus subtilis. Journal of Bioscience and Bioengineering 91 1 16 20
  80. 80. Schurgers I. J. Knapen M. H. J. Vermeer C. 2007 Vitamin K2 improves bone strength in postmenopausal women International Congress Series 1297 179 187
  81. 81. Tsukamoto Y. Ichisse H. Kakuda H. et al. 2000 Intake of fermented soybean (natto) increases circulating vitamin K2 (menaquinone-7) and γ-carboxylatedosteocalcin concentration in normal individuals. Journal of Bone and Mineral Metabolism 18 216 222
  82. 82. Wu W. Ahn B. 2011 Improved Menaquinone (Vitamin K2) production in Cheonggukjang by optimization of the fermentation conditions. Food Science and Biotechnology 20 6 1585 1591

Written By

Liyan Chen, Ronald L. Madl, Praveen V. Vadlani, Li Li and Weiqun Wang

Submitted: 03 April 2012 Published: 20 February 2013