Microsoft Word - 11-Agra_30895.doc 378 Original Article Biosci. J., Uberlândia, v. 32, n. 2, p. 378-383, Mar./Apr. 2016 EFFECT OF GERMINATION ON MAIN PHYSIOLOGY AND BIOCHEMISTRY METABOLISM OF SORGHUM SEEDS EFEITO DA GERMINAÇÃO NO PRINCIPAL METABOLISMO FISIOLOGICO E BIOQUÍMICO DE SEMENTES DE SORGO Runqiang YANG 1 ; Peng WANG 1 ; Maha F. ELBALOULA 1,2 ; Zhenxin GU 1 1. College of Food Science and Technology, Nanjing Agricultural University, Nanjing 210095, People's Republic of China; 2. Department of Food Science and Technology, College of Agricultural Studies, Sudan University of Science and Technology. Bahri– Shambat, Khartoum, 13314, Sudan. guzx@njau.edu.cn ABSTRACT: The main physiology and biochemistry metabolism including amino acids composition and gamma-aminobutyric acid (GABA) content of sorghum during 3-day germination period was investigated. Respiratory rate increased during germination. Protease activity, free amino acid and reducing sugar content increased with germination time. While moisture, protein, fat and starch content decreased, significantly. Meanwhile, amino acid composition redistributed and the relative content of essential amino acids increased except for leucine and valine. In addition, some nonessential amino acids content such as proline, glycine and histidine was largely enhanced by germination. GABA content increased about 3 folds after germination. Furthermore, combining tannin (the main anti- nutritional factor) was converted to be free and solvable. These results greatly suggest that germinated sorghum could be a functional food rich in GABA and other health-promoting nutrients. KEYWORDS: Sorghum. Germination. Physiology and biochemistry. Gamma-aminobutyric acid. Tannin. INTRODUCTION Sorghum (Sorghum bicolor L. Moenc) is a major crop around the world with many unique characteristics. It has become an important source of energy, protein, minerals, antioxidant, vitamins and gluten free diet for the poor people of Africa and Asia (BELTON; TAYLOR 2004; DICKO et al., 2006). Therefore, the improvement of the available nutrients is critically important for food science (BELTON; TAYLOR 2004). Many biochemical researches were conducted to enhancing the nutritional composition of sorghum. As a biochemical method, germination has been widely used to improve functional properties (GUAJARDO-FLORES et al., 2014, JANNOEY et al., 2010). Germination could modify sorghum protein composition and thus promoting its nutritional quality, as well as improve sorghum amino acid composition (CHAVAN et al., 1989). During germination, a large number of significant changes occur including activation of intrinsic amylases, proteases, and fiber-degrading enzymes (BENITEZ et al., 2013; LOYMA et al., 2012), etc., which partially degrade the complex substance into simple. Especially, gamma-aminobutyric acid (GABA) was accumulated significantly (YANG et al., 2013), while tannin and antinutritional factors were degraded or released (KHANDELWAL et al., 2010; LUO; XIE 2013). In this study, the main physiology and biochemistry metabolism changes of sorghum seeds during germination was investigated. The objective of this study was to supply some data for developing sorghum food with high nutritional value and low content of anti-nutritional factors. MATERIAL AND METHODS Materials Seeds of Sudanese sorghum cultivars locally known as Butanna, harvested in October 2012, were obtained from the Sudanese Arab company (Khartoum, Sudan). Acetonitrile was of high- performance liquid chromatography (HPLC) grade. Other chemicals and reagents were of analytical grade and purchased from Shanghai Institute of Biochemistry (Shanghai, China). Seed germination The sorghum seeds were surface-sterilized with 1.0% (v/v) sodium hypochlorite for 30 min at room temperature (25 ± 2 °C) and then steeped in deionized water for 6 h. Sorghum seeds were placed in a culture plat with filter paper and 10 mL of deionized water was added. Germination in the dark for three days at 32 ± 2 °C and samples were taken every day. After germination, sprouts were collected and stored at -20 °C until further analyses. Determination of biochemical composition Crude fat (solvent extraction), starch and crude protein (Kjeldahl, multiplying factor of 6.25) contents were determined according to standard Received: 14/07/15 Accepted: 20/01/16 379 Effect of germination… YANG, R. et al. Biosci. J., Uberlândia, v. 32, n. 2, p. 378-383, Mar./Apr. 2016 methods (AOAC, 2000). Free amino acid content was estimated using aninhydrin colorimetric method. Reducing sugars were estimated using MILLER et al. (1959) method. Determination of germination percentage Germination percentage was determined during the three days of germination. The definition of seed germination was when the emerging radical elongated to 1 mm. Germination percentage was calculated as follow: No. of germinated seeds GR% 100 No. of total seeds = × . Determination of root length Twenty germinated sorghum seeds were taken as one sample group and calibrated by ruler (cm) for measuring of the root length every 24 h. Determination of respiratory rate Fresh germinated and ungerminated sorghum were put into sealed container at 28 °C for 1 h. Then CO2 concentration was measured using an infrared gas analyzer (LB-BZ, Qingdao Loobo Environmental Protection Technology Co., Ltd, Qingdao, China). The respiratory rate was expressed as milligram per gram per hour. Determination of amino acid composition Amino acid composition was determined using amino acid analyzer (Hitachi L8900, Hitachi Co., Japan) according to the method described in AOAC (2000). Amino acids were expressed as g 100 g-1 protein on dry weight basis. Determination of GABA GABA content was determined according to Yang et al. (2013) using HPLC system (Agilent, GMI, Ramsey, MN, USA). Determination of Tannin Tannin content of germinated sorghum flour was determined according to the modified Vanillin- HCl methanol method as described by Khandelwal et al. (2010) Statistical analysis An analysis of variance (ANOVA) of the data was performed, and a least significant difference (LSD) test with confidence interval of 95% was used to compare the means. RESULTS AND DISCUSSION Germination percentage, root length and respiratory rate of germinated sorghum The change in germination percentages, root length and respiratory rate of sorghum seeds during germination are presented in Figure 1. About 97.1% of the germination percentage was observed at the 1st day of germination. Root length increased with germination, the length of the root reached 1.36 cm and 2.06 cm at the 2nd and 3rd day of germination, respectively. The consumption of oxygen in germinated sorghum seeds reaches its maximum rate between the 2nd and 3rd day of germination, a low rate of respiration metabolism was measured at the 1st day. The respiration rate is related to the activation of vigorous enzymes in seeds. During germination, seeds consumed biochemical nutrients and energy, derived from the metabolism mechanism and the anabolic reactions. Germination time (day) 0 1 2 3 R es p ir o tr y r at e ( m g. g -1 h -1 F W ) 0.0 0.2 0.4 0.6 0.8 1.0 R o o t le n gt h (c m ) 0.0 0.5 1.0 1.5 2.0 2.5 G er m in at io n ra te ( % ) 0 20 40 60 80 100 120 R R R L G R d c b a d c b a d a a b Figure 1. Changing pattern in germination rate (GR), root length (RL) and respiratory rate (RR) of sorghum during germination. Values are the means of triplicate analyses. Error bars show the standard deviation. Lower case letters reflect the significance of differences (p < 0.05). 380 Effect of germination… YANG, R. et al. Biosci. J., Uberlândia, v. 32, n. 2, p. 378-383, Mar./Apr. 2016 Germination increased the small molecular nutrients of sorghum seeds The nutritional contents of germinated sorghum are shown in Table 1. Germination for 1, 2 and 3 days showed significant difference (p< 0.05) in nutritional contents compared with the raw sorghum seeds. The contents of crude protein, crude fat and starch reduced, whereas that of free amino acids and reducing sugars increased with germination time. Free amino acids and reducing sugars increased by 2 and 4 folds at 3rd day of germination, respectively. Germination caused degradation of the stored nutrients like starch and protein to soluble sugars and free amino acids by hydrolytic enzymes to meet the seed requirements and the embryo growth. Crude fat, crude protein and starch are major sources of nutrients during germination. Starch and protein degradations indicated the interference with metabolic systems work on reserve starch and protein by the enzymes amylases and proteases. Fat content decreased during germination, because germinated seeds need another source of energy rather than sugars which have been already utilized. Table 1. Effect of germination time on biochemical composition (g 100g-1) of sorghum. Index Germination time (day) 0 1 2 3 Starch 69.42±1.69a 66.21±0.62b 63.57±1.24b 60.08±2.14c Protein 9.99±0.34a 9.15±0.28b 8.89±0.14bc 8.65±0.12c Crude fat 4.74±6.8a 3.52±0.10b 3.02±0.13bc 3.22±0.06bc Free amino acid 0.82±0.01c 0.95±0.06c 1.27±0.8b 1.66±0.07a Reducing sugar 3.78±0.10c 10.37±0.33b 10.45±0.05b 14.65±0.47a Values are means and standard deviation of three determinations (n = 3). Values followed by different superscript letters in a column are significantly (p < 0.05) different from each other. Germination redistributed essential amino acid composition The nutritional value of food dietary protein can be assessed by measuring the type and quantity of essential amino acids present. The results showed that essential amino acids content in 1-day germinated sorghum was lower than that in raw (Table 2). But they were increasing with the germinating time. When germinating for 3 days, phenylalanine, lysine, methionine and tyrosine content increased by 14.49%, 21.46%, 56.14% and 17.00%, respectively, compared with that in raw. It could be concluded that germination enhanced the content of most of the essential amino acids especially limiting amino acids. Table 2. Essential protein amino acids content (g 100g-1 protein) of sorghum cultivar Butana during germination. Amino acid Raw Germinated time (day) 1 2 3 Leucine 14.83±1.77a 8.42±0.46c 13.44±1.14a 12.81±0.74ab Threonine 3.71±0.45a 2.08±0.07b 3.54±0.12a 3.87±0.21a Valine 6.30±0.33a 4.13±0.56b 6.41±0.65a 6.25±0.77a Phenylalanine 6.97±0.94a 4.78±0.35b 7.38±0.33a 7.98±0.12a Lysine 2.47±0.11b 1.47±0.04c 2.65±0.06b 3.00±0.04a Methionine 1.14±0.08b 1.10±0.05b 1.03±0.09b 1.78±0.09a Tyrosine 4.00±0.24b 2.35±0.07c 4.30±0.31ab 4.68±0.05a Isoleucine 4.03±0.09a 2.30±0.11b 3.95±0.17a 4.23±0.34a Values are means and standard deviation of three determinations (n = 3). Values followed by different superscript letters in a row are significantly (p < 0.05) different from each other. Germination increased GABA content of sorghum seeds There was a gradual and significant (p< 0.05) increase in GABA content during three days germination (Figure 2). Its content in germinated sorghum increased by about 5 times at the 3rd day of germination. This enrichment may be due to the decrease in glutamate content (BAI et al., 2008), indicating that germination not only can increase essential protein amino acids, but also increase other non protein amino acids with functions such as GABA, etc. 381 Effect of germination… YANG, R. et al. Biosci. J., Uberlândia, v. 32, n. 2, p. 378-383, Mar./Apr. 2016 Germination time (day) 0 1 2 3 G A B A c o n te n t (µ g g -1 D W ) 0 50 100 150 200 250 300 350 a b c d Figure 2. Changing patterns in GABA content of sorghum during germination. Values are the means of triplicate analyses. Error bars show the standard deviation. Lower case letters reflect the significance of differences (p < 0.05). Germination converted binding tannin of sorghum seeds to free Germination for 3 days recorded the highest tannin content (Figure 3). Generally, tannin is combined with protein, polysaccharide and cellulose, etc. in seeds. During germination, endogenous enzymes were activated to degrade storage substances to small micromolecular and tannin was released to be detectable significantly using conventional method (AHMED et al., 1996; ELKHIER; HAMID 2008). In addition, the kernel coat did not affect during the germination process, since tannins is condense there and the most edible part is the cotyledon. So that kernel coat is mare in weight compared with the remained cotyledon weight. Therefore, overall tannin content was increased. However, some researches reported that germination reduce the tannin content, this can be due to solubilisation by enzymes because germination promote the hydrolytic enzymes (DEWAR et al., 1997; IDRIS et al., 2006). In the present study, the results disagree with previous researches. Also this could be a result of solubilization of tannin when the seeds were soaked in water and migration of tannin to the outer layer during germination, as indicated by the browning of the germinated seeds. Germination time (day) 0 1 2 3 T an n in c o n te n t (% ) 0.0 0.1 0.2 0.3 0.4 a ab ab b Figure 3. Tannin content during germination. Values are the means of triplicate analyses. Error bars show the standard deviation. Lower case letters reflect the significance of differences (p < 0.05). CONCLUSIONS The root length, respiratory rate, free amino acid and reducing sugar increased during sorghum germination, whereas a decreasing trend occurred in its germination rate, moisture content, crude protein, crude fat and starch content. 382 Effect of germination… YANG, R. et al. Biosci. J., Uberlândia, v. 32, n. 2, p. 378-383, Mar./Apr. 2016 Germination increased essential amino acids content especially for limiting amino acids. In addition, it was confirmed that germination increased GABA content while released tannin in sorghum. All these results supported that germination could improving nutrients of sorghum which can be used to produce functional food formulations particularly for children and geriatric people. ACKNOWLEDGMENTS We are grateful for the financial support from Innovation Training Project for College Students of NAU and the Project (1518C04) and the Priority Academic Program Development of Jiangsu Higher Education Institutions (PAPD). RESUMO: O principal metabolismo fisiologico e bioquímico incluindo composição de aminoácidos e teor em ácido gama-aminobutírico (GABA), do sorgo durante o período de germinação 3-dia foram investigados. A frequência respiratória aumentou durante a germinação. A atividade de proteases, aminoácidos livres e redução do teor de açúcar aumentou com o tempo de germinação. Enquanto umidade, proteína, gordura e teor de amido diminuiram, significativamente. 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