Introduction
Soybean seed is one of the major food sources for protein, oil, carbohydrates, isoflavones, and many other nutrients to humans and animals. Soybean seed is composed of 40% protein. Demand of soybean and soybean products has increased in recent years because of high quantity and quality of soybean protein. Also, several antinutritional factors and allergenic proteins in the raw mature soybean are exist. Kunitz Trypsin Inhibitor (KTI) protein, lectin protein and 7S α‘-subunit protein are main antinutrients responsible for reducing the nutritional value of unprocessed soybean.
Soybean Kunitz Trypsin Inhibitor (KTI) protein is a small and non-glycosylated protein containing 181 amino acid residues with 21.5 kDa. KTI protein was first isolated and crystallized from soybean seeds by Kunitz [11]. Kunitz trypsin inhibitor protein strongly inhibits trypsin, thus reducing food intake by diminishing digestion and absorption. Five electrophoretic forms of KTI have been discovered. The genetic control of four forms, Tia , Tib , Tic , and Tid , has been reported as a codominant multiple allelic series at a single locus [5, 16, 20]. Orf and Hymowitz [16] found that the fifth form does not exhibit a soybean trypsin inhibitor-A2 band and is inherited as a recessive allele designated ti. Orf and Hymowitz [16] identified two soybean accessions (PI157440 and PI196168) which lacks KTI protein from USDA germplasm collection. The Ti locus has been located on linkage group 9 in the classical linkage map of soybean [4,6], which was integrated in linkage group A2 (chromosome 8) of the USDA/Iowa State University soybean molecular linkage map [1].
Soybean lectin protein is a glycoprotein with a molecular weight of 120 kDa with four similar subunits [17]. The soybean lectin is able to link to carbohydrate chains found in glycoproteins and glycolipids and present a strong affinity for N-acetyl-D- galactosamine and to a lower extent for Dgalactose. This lectin-carbohydrate interaction will consequently result into a changed morphology of the intestinal epithelium, as well as a decrease in the digestion and absorption of nutrients [18]. The presence of seed lectin is controlled by a single dominant gene designated Le and the homozygous recessive lele results in the lack of lectin [15]. Ti and Le loci were segregated independently [12, 13, 16]. Recently, a new soybean line with triple null recessive genotypes (ti/ti-le/le-p34/p34) was developed [19].
Soybean β-conglycinin (7S globulin) and glycinin (11S globulin) are the major components of storage protein in soybean. β-conglycinin consists of three subunits, α‘, α, β and exhibits poorer nutritional and food processing properties than glycinin [22]. Also, β-conglycinin contains much less sulfur-containing amino acid, methionine and cysteine, than glycinin [9]. Several mutant lines affecting accumulation of β-conglycinin have been identified in soybean germplasms. Kitamura and Kaizuma [7] identified Keburi, which was characterized by the absence of the α’-subunit of β-conglycinin. Kitamura et al. [8] reported that the absence of α‘-subunit were controlled by single recessive alleles, cgy1. Wild soybean line, QT2, which lacks α’-subunit was also identified. In the QT2 line, the deficiency of α‘-subunit is controlled by a single dominant gene, Scg [2]. Scg gene was inherited independently with cgy1 gene. Studies also showed that absence of the α’-subunit in QT2 was inherited independently from the presence of lipoxygenase isozymes. Hayashi et al. [3] identified AFLP marker to be tightly linked to the gene for deficiency of the β-conglycinin. Highly negative correlation between the contents of β-conglycinin and glycinin was reported by Ogawa et al. [14]. Breeding of soybean containing large amount of glycinin compared with current varieties is possible by selecting strain of soybean that does not exhibit or lacks α‘,α, and β-subunits of β-conglycinin.
Development of new soybean cultivar with free of KTI, lectin, 7S α' subunit proteins is needed to improve the nutrition values and to modify the food processing properties of soybeans. Also, this cultivar enhances the utilization of soybean in food as well as feed uses. The objective of this research was to develop new soybean genotype with triple recessive alleles (titilelecgy1cgy1) for KTI protein, lectin protein and 7S α' subunit protein. This is the first report on soybean strain with titilelecgy1cgy1 genotype (KTI, lectin and 7S α' subunit protein free.
Materials and Methods
Genetic population
Three parents (Gaechuck#2, PI506876, and Le-16) were used to develop genetic population. Gaechuck#2 parent has titiLeLeCgy1Cgy1 genotype (KTI protein absent, lectin and 7S α' subunit protein present), yellow seed coat and black hilum. PI506876 parent has TiTiLeLecgy1cgy1 genotype (KTI and lectin protein present, 7S α' subunit protein absent), yellow seed coat and brown hilum. Le-16 parent has TiTileleCgy1Cgy1 genotype (KTI protein present, lectin protein absent, 7S α' subunit protein present), greenish yellow seed coat and yellow hilum. Genotype for Ti (ti), Le (le), and Cgy1 (cgy1) alleles of three parents is presented in Table 1. The seeds of Gaechuck#2, PI200508, and Le-16 parents were planted to cross in a greenhouse. The crosses of Gaechuck#2 (titiLeLeCgy1Cgy1) × PI506876 (TiTiLeLecgy1cgy1) and Gaechuck#2 (titiLeLeCgy1Cgy1) × Le-16 (TiTileleCgy1Cgy1) were made and F1 seeds were obtained. F1 seeds obtained were planted in greenhouse. F2 seeds from F1 plant were harvested. Two new genotypes (titiLeLecgy1cgy1 and titileleCgy1 Cgy1) were selected from the F2 plant population. The cross of titiLeLecgy1cgy1 x titileleCgy1Cgy1 was made and F1 seeds were obtained. F1 seeds obtained were planted in greenhouse. F1 hybridity was confirmed on morphological traits. F2 seeds were harvested. The F2 seeds were analyzed to screen the seed with titilelecgy1cgy1 genotype (KTI, lectin and 7S α' subunit protein free).
Table 1. Genotype for Ti (ti), Le (le), and Cgy1 (cgy1) alleles of parents used in this experiment
Determination of lectin protein by Western blot analysis
Proteins of parent, each F2 seed, random F3 seed and F4 seed were separated by 10% or 12% SDS-PAGE, and transferred on to Immobilon-P membrane (PVDF, Millipore). After blocking for 2 hr in TBS buffer [20 mM Tris (pH7.5), 150 mM NaCl, and 0.1% Tween 20 ] with 5% nonfat dried milk (Carnation, Glendale, CA) at room temperature, the membrane were incubated with lectin antibody for 1 hr. After washing in TBS buffer three times, the blot was in- cubated with a horseradish peroxidase conjugated secondary antibody, and the complex was visualized using an enhanced chemiluminescence kit (Amersham, Bucking-hamshire, UK). The thickness of band was then determined visually.
Determination of KTI protein by Western blot analysis
Proteins of parent, each F2 seed, random F3 seed and F4 seed were separated by 10% or 12% SDS-PAGE, and transferred onto Immobilon-Pmembrane (PVDF, Millipore). After blocking for 2 hr in TBS buffer [20 mM Tris (pH7.5), 150 mM NaCl, and 0.1% Tween 20] with 5% nonfat dried milk (Carnation, Glendale, CA) at room temperature, the membrane were incubated with KTI antibody for 1 hr. After washing in TBS buffer three times, the blot was incubated with a horseradish peroxidase conjugated secondary antibody, and the complex was visualized using an enhanced chemiluminescence kit (Amersham, Bucking-hamshire, UK). The thickness of band was then determined visually.
Determination of 7S α'-subunit protein by SDSPAGE
Crude proteins from parent, each F2 seed, random F3 seed and F4 seed were extracted to determine the presence or absence of α‘-subunit protein of β-conglycinin electrophoretically. A piece of cotyledon from parent and each F2 seed was removed and was incubated for 30 min (at room temperature) in 1 ml Tris-HCl, pH8.0, containing 1.56%v/v βmercaptoethanol. After centrifugation, 50 ul of the supernatant was added to an equivalent amount of 5X sample buffer [10%w/v sodium dodecyl sulfate (SDS), 50%v/v glycerol, 1.96%v/v β-mercaptoethanol, 1M Tris-HCl, pH 6.8]. The samples were boiled at 97o C for 5 min and then centrifuged.Two microliters of the supernatant were loaded on a 12% acrylamide SDS polyacrylamide gel electrophoresis (SDS-PAGE) medium gels in Owl Separation Systems Inc (Model:P9DS, Portsmouth, NH, USA). Electrophoresis was performed at 120 V for 7 hr. Gels were stained overnight in an aqueous solution of 0.25 g Coomassie blue R250, 10% acetic acid, and 45% methanol. The gels were then destained with destaining solution (5% acetic acid, 14% methanol) for several hours. A Wide-Range SDS-PAGE molecular mass standard (Sigma MarkerTM, Product Code: M4038, St.Louis MO, USA) containing the 72 kDa (for α’-subunit) was used to aid recognition of samples lacking the α‘- subunit of β-conglycinin protein.
Selection of titilelecgy1cgy1 (free of KTI, lectin, and 7S α' subunit proteins) genotype
The F2 seeds with titilelecgy1cgy1 genotype (KTI, lectin and 7S α' subunit protein free) were planted to advance F2 plant generation. F2 plants with a proper agronomic traits were individually harvested. F3 seeds with titilelecgy1cgy1 genotype were planted to F3 plant generation. F3 plants with a proper agronomic traits were individually harvested. Random F4 seeds from F3 plants harvested were used to confirm KTI protein free, lectin protein free, and 7S α' subunit protein free. Flower color, plant height, growth habit, 100-seed weight, seed coat color, and hilum color were recorded on the F4 plant generation.
Mean values of plant height and 100-seed weight were compared by Duncan’s multiple range test at the 5% level. Scheme for development of titilelecgy1cgy1 genotype (KTI, lectin and 7S α' subunit protein free) is presented in Fig. 1.
Fig. 1. Scheme for development of soybean strain with titilelecgy1cgy1 genotype (KTI protein free, lectin protein free and 7S α' subunit protein free).
Results and Discussion
F1 seeds were obtained from the cross of titiLeLecgy1cgy1 × titileleCgy1Cgy1. Genotype of F1 seeds obtained was titiLeleCgy1cgy1 and lectin and 7S α' subunit proteins were observed. F2 seeds were harvested from F1 hybrid plant. Both lectin protein of 120 kDa and 7S α' subunit protein of 72 kDa were segregated in the F2 seed generation. The 3:1 segregation ratios for inheritance of lectin and 7S α' subunit proteins were observed in the F2 seed generation. Among F2 seeds obtained, 45 F2 seeds with cgy1cgy1 genotype (7S α' subunit protein free) were selected. Four F2 seeds with titilelecgy1cgy1 genotype (KTI, lectin and 7S α' subunit protein free) were selected and were planted. This result supports that absence of KTI, lectin, and 7S α‘-subunit proteins was controlled by a single recessive gene [5, 8, 12, 15]. Four F2 plants were individually harvested and two F2 plants with a proper agronomic traits were selected. Two F3 seed strains were planted and one F3 plant strain with a proper agronomical traits such as plant type, plant height, seed quality, and 100-seed weight was finally selected. Random F4 seeds were used to confirm absence for KTI, lectin and 7S α' subunit proteins (Fig. 2).
Fig. 2. Confirmation of Kunitz Trypsin Inhibitor (KTI) protein free (A), lectin protein free (B), and 7S α' subunit protein free (C) in the current cultivar (“Daewonkong”) and new strain. C: “Daewonkomg” (TiTiLeLeCgy1Cgy1 genotype), S: new strain (titilelecgy1cgy1 genotype). +, -: presence and absence of KTI, lectin, and 7S α' subunit proteins, respectively.
KTI, lectin, and 7S α' subunit proteins were not observed in the mature F4 seed of new strain. However, in the seed of “Daewonkong” cultivar, KTI, lectin, and 7S α' subunit proteins were shown (Fig. 2). This result indicates that genotype of new strain is titilelecgy1cgy1. Agronomic traits such as flower color, growth habit, plant height, 100-seed weight, seed coat color, and hilum color for “Daewonkomg” (TiTiLeLeCgy1Cgy1 genotype) and new F4 plant strain (titilelecgy1cgy1 genotype) are presented in Table 2.
Table 2. Agronomic traits of cultivar and new strain developed in this experiment
a-b: Different letters in the column are significantly different by DMRT at 5%.
New strain has purple flower, determinate growth habit, and light yellow pods at maturity. The seed of new strain has buffer hilum color and yellow seed coat color. Plant height of new strain was 58 cm compared to the “Daewonkong” cultivar of 46 cm. The 100-seed weight of new strain was 27.1 g smaller than that of "Daewonkong" (29.0 g). Plant type harvested and seed of new strain with titilelecgy1cgy1 genotype (KTI, lectin, and 7S α' subunit proteins free) is shown in Fig. 3.
Fig. 3. Plant (A) and seed (B) of new soybean strain (titilelecgy1cgy1 genotype) with Kunitz Trypsin Inhibitor protein free, lectin protein free, and 7S α' subunit protein free.
KTI, lectin, and 7S α' subunit proteins are major antinutrients responsible for reducing the nutritional value of unprocessed soybean. Presence of these proteins in mature raw soybean seeds requires heating step to denature the activity of these antinutritional components. However, excessive heat treatment may lower amino acid availability. The genetic elimination removal of these components could be an alternative to the heat treatment. Breeding of soybean cultivar with free of KTI, lectin, and 7S α' subunit proteins is needed to improve the nutrition values and to modify the food processing properties of soybeans. This is the first new soybean strain with titilelecgy1cgy1 genotype (KTI pro- tein free, lectin protein free, and 7S α' subunit protein free). New strain developed in this research will be used to improve new yellow soybean cultivar with high quality and function.
Acknowledgement
This research was supported by Korea Institute of Planning and Evaluation for Technology in Food, Agriculture and Forestry (Research number:119011-3).
The Conflict of Interest Statement
The authors declare that they have no conflicts of interest with the contents of this article.
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