Nova Biotechnologica et Chimica 15-1 (2016) 1 DOI 10.1515/nbec-2016-0001 © University of SS. Cyril and Methodius in Trnava IN VITRO REGENERATION POTENTIAL OF SEVEN COMMERCIAL SOYBEAN CULTIVARS (Glycine max L.) FOR USE IN BIOTECHNOLOGY JANA SOJKOVÁ1, IWONA ŽUR2, ZUZANA GREGOROVÁ1,3, MÁRIA ZIMOVÁ1,3, ILDIKÓ MATUŠÍKOVÁ4, DANIEL MIHÁLIK5,6, JÁN KRAIC5,6, JANA MORAVČÍKOVÁ3* 1Department of Botany and Genetics, Faculty of Natural Sciences, The Constantine Philosopher University, Nábrežie mládeže 91, SK-949 74 Nitra, Slovak Republic 2Polish Academy of Sciences, Franciszek Gorski Institute of Plant Physiology, Niezapominajek 21, PL-30-239 Kraków, Polland 3Institute of Plant Genetics and Biotechnology Slovak Academy of Sciences, Akademická 2, P.O. Box 39A, SK-950 07 Nitra, Slovak Republic (jana.moravcikova@savba.sk) 4Department of Ecochemistry and Radioecology, Faculty of Natural Sciences, University of SS. Cyril and Methodius in Trnava, Nám. J. Herdu 2, SK-917 01 Trnava, Slovak Republic 5Department of Biotechnology, Faculty of Natural Sciences, University of SS, Cyril and Methodius in Trnava, Nám. J. Herdu 2, SK-917 01 Trnava, Slovakia 6Research Institute of Plant Production, National Agricultural and Food Center, SK-921 68 Piešťany, Slovakia Abstract: This work is aimed to evaluate in vitro regeneration potential of seven commercial soybean varieties Bohemians, Cardiff, Gallec, Merlin, Moravians, Naya and Silensia (Glycine max L.) cultivated in Central Europe. Our results showed the half-seeds could be effectively used as an explant source for all tested cultivars. The regeneration was initiated on the media containing growth regulators 1.67 mg.l-1 BAP and 0.25 mg.l-1 GA3. Within the first five days culture, green chlorophyll-containing explants were observed with frequency from 18.3% to 55.9%. Two weeks later, the explants responded by production of calli with the efficiency up to 83.0%. First shoots appeared after 2-3 weeks of subculture on the media. The soybean regeneration showed to be genotype-dependent with variable efficiencies from 5.7% (cv. Naya) to 37.7% (cv. Gallec). The cultivars Cardiff, Merlin and Gallec appear to be the most promising candidates for further biotechnological use. Application of antioxidants such as L-cysteine, dithiothreitol and sodium thiosulfate does not have effect on the explant regeneration for the first five days. Key words: antioxidants, half-seeds, chlorophyll fluorescence, in vitro, soybean 1. Introduction Soybean (Glycine max (L.) Merrill) is one of the major legume crops in the world. The seeds are important source of protein and edible vegetable oil for livestock, human consumption and industrial sector. Soybean is one of the few plants that contain all eight amino acids essential for human health. The consumption of soybean reduces cancer, cholesterol, osteoporosis and heart diseases (BIRT et al., 2004). Because soybean has been growing for many centuries around the world under Bereitgestellt von Slovenská poľnohospodárska knižnica | Heruntergeladen 17.01.20 13:55 UTC 2 Sojková, J. et al. different climatic conditions, there is a wide range of soybean varieties available. The major producers are the United States, Brazil and Argentina. The first genetically modified (GM) Roundup Ready soybeans were planted in the USA in 1996. In 2011-2012 soybeans were grown on about 30 million hectares in the USA, with Roundup Ready GM soy contributing 93–94% of the production (BØHN et al., 2014). The successful application of genetic engineering in plant improvement is dependent on availability of the efficient in vitro regeneration protocol. The regeneration of soybean has been reported using immature embryos (BARWALE et al., 1986), immature cotyledons (ISHIMOTO et al., 2010), hypocotyls (WANG and XU, 2008), mature cotyledonary nodes (LIU et al., 2008) or half-seeds (PAZ et al., 2006). However, the regeneration efficiency was variable depending on the genotype and the explant type used (reviewed by VERMA et al., 2014). The half-seeds represent alternative cotyledonary explants derived from mature soybean seeds. The half-seed system has been developed as a demand for elimination of deliberate tissue wounding prior Agrobacterium infection (PAZ et al., 2006). Using the half-seeds as an explant source, the regeneration efficiency and the number of obtained transgenic plants were 1.5-fold higher (PAZ et al. 2006) compared to the cotyledonary node method (PAZ et al. 2004). Many plant tissue cultures respond to the culture manipulation by oxidative browning and necrosis that typically result in poor regeneration (reviewed by DAN et al. 2008). Beside, tissue browning is associated with plant defence response to infection with Agrobacterium (KUTA and TRIPATHI, 2005). Several studies reported that adding antioxidants into the culture media can considerably improve plant regeneration (reviewed by VERMA et al., 2014). Adding of L-cysteine and other thiol compounds sufficiently inhibited wound- and Agrobacterium-induced responses of soybean cotyledonary node cells and increased the number of regenerated transgenic plants (OLHOFT and SOMERS, 2001; OLHOFT et al., 2001). Therefore, thiol compounds are common part of the regeneration media in soybean cotyledonary node and half-seed transformation and regeneration systems (PAZ et al., 2004; PAZ et al., 2006; WANG and XU, 2008; KIM et al., 2012). In this work, seven commercial soybean varieties Bohemians, Cardiff, Gallec, Merlin, Moravians, Naya and Silensia were studied for their ability to regenerate in vitro. The half-seeds were used as the explant source. The regeneration approach designed here led to obtaining of plants from each of tested cultivars, however, with variable efficiencies. This is (up to our knowledge) the first report on in vitro regeneration of these commercial soybean cultivars. 2. Material and methods 2.1 Plant material and explant preparation The soybean cultivars (Glycine max (L). Merrill) Bohemians, Cardiff, Gallec, Merlin, Moravians, Naya and Silensia were obtained from the company Matex s.r.o (Veškovce, Slovak Republic). Mature seeds were surface-sterilized for 20 hours Bereitgestellt von Slovenská poľnohospodárska knižnica | Heruntergeladen 17.01.20 13:55 UTC Nova Biotechnologica et Chimica 15-1 (2016) 3 using chlorine gas produced by mixing 3.5 ml 12 mol.l-1 with 100 ml commercial bleach (SAVO) described by DI et al. (1996). One day prior experiments, sterilised seeds were soaked in sterile water for about 20 hours in Petri dishes covered with aluminium foil. The cotyledons were separated by longitudinal cut along hilum. The half-seed explants were obtained by the excision of the embryogenic axis. 2.2 Plant regeneration The half-seed explants were cultivated on callus induction medium (CIMA, Table 1) lined with sterile filter paper. The explants were placed adaxial side (flat side) down on the medium. Following 5 days, the explants were transferred on the shoot-induction medium (SIM, Table 1) so the nodal end of the half-seed explant was imbedded into the media. After 14 days, the explants were transferred to the fresh SIM medium. After 5 weeks of culture, the explants were transferred on the shoot elongation medium (SEM, Table 1). The explants were regenerated at 24°C and 16 h/ 8 h light/dark photoperiod under 50 μE m-2 s-1 light intensity. 2.3 Chlorophyll fluorescence measurement Chlorophyll fluorescence was measured using portable fluorometer Handy FluorCam FC 1000-H (PSI s.r.o. Czech Republic). Measurement was performed on Petri dishes containing half-seed explants (10 explants per Petri dish). Petri dishes containing explants were placed in the dark for 30 min prior to the measurement. The chlorophyll fluorescence was measured directly from the top of dishes with removed lids according to the protocol “short” Kautsky effect in continuous light. We measured minimum chlorophyll fluorescence (F0), variable fluorescence (Fv = Fm - F0) and quantum efficiency of open PSII centers in a dark-adapted state (QYmax = Fv/Fm). 2.4 Histochemical staining The cell viability was determined after staining with a 0.25 % (w/v) Evans blue for 30 min at room temperature and subsequent washing three times with distilled water, for 10 min each according to TAMAS et al. (2008). Lipid peroxidation was detected using Schiff´s reagent for 60 min as described previously POMPELLA et al. (1987) 2.5 Explant sampling and statistical analyses The sets of analysed explants for in vitro regeneration potential were subjected to analyses at (1) 5 th day and (2) 5th weeks culture. For chlorophyll fluorescence measurement, the explants were analysed at 5th day- culture on the callus-induction media with or without antioxidants (CIMA or CIMB, respectively). Bereitgestellt von Slovenská poľnohospodárska knižnica | Heruntergeladen 17.01.20 13:55 UTC 4 Sojková, J. et al. The cell viability and lipid peroxidation was detected on explants immediately after separation of cotyledons and excision of embryogenic axis. Data are presented as the means of three replications. Statistical significance of the experimental results was evaluated by Duncan’s test with help of STATISTICA_version 7.1. Table 1. Composition of media used in regeneration experiments. CIMA 0.32 g.l-1 Gambor B5 including vitamins (Duchefa), 2.78 mg.l-1 FeSO4.7H2O, 3.72 mg.l -1 NaEDTA, , 4.26 mg.l-1 MES, 30 g.l-1 sacharose, 1.67 mg.l-1 BAP, 0.25 mg.l-1 GA3, 5 g.l -1 agar pH 5.4, 400 mg.l-1 L-cysteine, 0.154 g.l-1 DTT, 0.158 mg.l-1 STS and 5 g.l-1 AgNO3. CIMB 0.32 g.l-1Gambor B5 including vitamins (Duchefa), 2.78 mg.l-1 FeSO4.7H2O, 3.72 mg.l -1 NaEDTA, 4.26 mg.l-1 MES, 30 g.l-1 sacharose, 1.67 mg.l-1 BAP, 0.25 mg.l-1 GA3, 5 g.l -1 agar pH 5.4 SIM 3.2 g.l-1 Gambor B5 including vitamins (Duchefa), 278 mg.l-1 FeSO4.7H2O, 372 mg.l-1 NaEDTA, , 0.64 mg.l-1 MES, 30 g.l-1 sacharose, 1.67 mg.l-1 BAP, 5 g.l-1 AgNO3, 7 g.l -1 agar pH 5.7 SEM 3.2 g.l-1 Gambor B5 including vitamins (Duchefa), 278 mg.l-1 FeSO4.7H2O, 372 mg.l-1 NaEDTA, 0.64 mg.l-1 MES, 20 g.l-1 sacharose, 0.5 mg.l-1 GA3, 0.1 mg.l-1 IAA, 1 mg.l-1 zeatín, 50 mg.l-1 asparagine, 7 g.l-1 agar pH 5.7 CIMA - callus induction medium, SIM - shoot induction medium, SEM - shoot elongation medium, MES - 2-(N-Morpholino) ethanesulfonic acid, BAP- benzylaminopurine, GA3 – gibberellic acid, DTT – 1,4 dithiothreitol, STS – sodium thiosulfate, IAA – indolyl acetic acid 3. Results and discussion Soybean is one of the most important crops worldwide. Presently, biotechnology offers soybean traits that provide healthier ingredients for our diets and the diets of farm animals, as well as increased disease and insect resistance. However, soybean is considered particularly difficult to transform due to different factors, including regeneration efficiency in vitro. Here we studied in vitro regeneration potential of selected soybean cultivars, yet not tested elsewhere, using the half-seeds as an explant source (Fig 1a). This type of the explant has been previously shown to be a convenient material not only for soybean regeneration itself (JANANI et al., 2013) but also for genetic modification via A. tumefaciens (PAZ et al., 2006; KIM et al. 2012). The regeneration efficiency was genotype dependent and ranged from 1.4% to 8.7%. The half-seed explants were prepared by splitting of imbibed seeds and excision of embryogenic axis. Such manipulation is very often accompanied with browning and necrosis of the affected tissue that can lead to poor in vitro regeneration. Generally, mechanical wounding is associated with production of reactive oxygen species (ROS), common components of plant defence response against various stresses (OROZCO-CÁRDENAS et al., 2001; DEMIDCHIK et al., 2015). However, ROS at low level regulate numerous plant biological processes (DEL RÍO et al., 2015). For example, soybean seed germination is regulated through ethylene production in response to ROS (ISHIBASHI et al., 2013). Contrary, high level of ROS promotes oxidative stress through oxidation of the cell compounds (DEMIDCHIK et al., 2015) and often leads to loss of cell function and apoptosis (MARNETT 2000). Bereitgestellt von Slovenská poľnohospodárska knižnica | Heruntergeladen 17.01.20 13:55 UTC Nova Biotechnologica et Chimica 15-1 (2016) 5 Fig. 1. Representative photos of in vitro regeneration process of the cv. Merlin. a) The half-seeds were prepared by splitting of imbibed seeds and excision of embryogenic axis and placed on the CIMA medium; b) The half seeds after five days culture on the CIMA medium; c) First shoots after two weeks subculture on the SIM medium; d) Shoots after five weeks subculture on the SIM medium. Bars 500 µm. Fig. 2. Detection of cell viability (a,b,c, d) and membrane lipid peroxidation (e, f, g, h) in the half-seeds after splitting and excision of the embryogenic axis. The cell death was determined using staining with Evans blue. The membrane lipid peroxidation was stained using Schiff´s reagent. a, c) histochemical staining with Evans blue in the explants of the cvs. Naya and Gallec (respectively); b, d) cross sections of the explants of the cv. Naya indicating cell death at the side of the embryogenic axis removing; e, g) histochemical staining with Schiff´s reagent in the explants of the cvs. Naya and Gallec (respectively); f, h) cross sections of the explants of the cv. Naya and Gallec (respectively) indicating the extent of the lipid peroxidation. Bars 500 µm. Bereitgestellt von Slovenská poľnohospodárska knižnica | Heruntergeladen 17.01.20 13:55 UTC 6 Sojková, J. et al. In our experiments, histochemical staining proved peroxidation of membrane lipids all over the surface of the half-seeds immediately after explant preparation (Fig. 2a, 2b). Besides, the stain was detected in the cross section of the half-seed explants (Fig. 2c, Fig 2d). The sides of wounding areas of death cells were detected histochemically as a result of the separation of cotyledons (Fig. 2e, 2f) and at the site of excision of embryogenic axis (Fig 2g, 2h). Similar histochemical patterns were observed for all cultivars. Several studies reported the inclusion of antioxidants in the culture media can prevent necrosis and consequently improve plant in vitro regeneration (reviewed by DAN 2008). Moreover, antioxidants can reduce cell damage following Agrobacterium-mediated transformation by inhibiting of wound- and plant pathogen- induced responses (OLHOFT et al., 2001, OLHOFT and SOMERS, 2001). In cotyledonary node transformation of soybean, adding a mixture of thiol compounds such as L-cysteine, dithiothreitol and sodium thiosulfate into the co-cultivation medium improved regeneration potential of transformed cells (OLHOFT et al., 2003; PAZ et al., 2004; WANG and XU, 2008; KIM et al., 2012). However, a high level of thiol compounds might also have a negative effect on in vitro regeneration. For example, the application of L-cysteine at concentration higher than 600 mg.l-1 resulted in reduced number of transformed soybean shoots (LIU et al., 2008). Thus, above mentioned thiol compounds were applied at concentrations (Table 1) recommended by others (OLHOFT et al., 2003; PAZ et al., 2004; KIM et al., 2012). The half-seeds were cultivated on the CIM medium supplemented with (CIMA) or without (CIMB) antioxidants. After 5 days culture on the media (Fig 1b), the chlorophyll fluorescence of the explants (QYmax) as an indicator of regeneration was measured (Fig. 3). The results showed the chlorophyll content significantly varied with genotype (at p≤0.001) (Table 2). We did not observe any negative effects of these compounds on the half- seed regeneration. However, the effect of thiols as protective agents against ROS produced by wounding was not statistically significant (Table 2). Nevertheless, considering that promising soybean cultivars are expected to be subjected to genetic modification via Agrobacterium, these thiols (Table 1) were also applied in our further regeneration experiments. It is well known the regeneration is essential requirement for transformation. Moreover, regeneration potential of transformed cells can be dramatically decreased also for plant genotypes that are routinely regenerated. For example, regeneration efficiency of 50% was reduced to 1.3% after Agrobacterium-mediated transformation of cotyledonary petiole explants of oilseed rape cultivar Campino (BOSZORADOVA et al., 2011). Thus, identifying genotypes with high regeneration potential represents one of the prerequisites for successful transformation experiments. Table 2. Variance analyses. Source a F empirical b Photosynthetic activity (1) 16.75 *** (2) 1.81 ns (1) × (2) 1.06 ns Regeneration efficiency (1) 52.27 *** a Effect of (1) genotype, (2) treatment with or without antioxidants Statistical significance at ***p≤0.001; ** p≤0.01; * p≤0.05; ns – not significant Bereitgestellt von Slovenská poľnohospodárska knižnica | Heruntergeladen 17.01.20 13:55 UTC Nova Biotechnologica et Chimica 15-1 (2016) 7 Fig. 3. Effect of antioxidants on the maximum quantum yield of PSII (QYmax = Fv/Fm). The Chlorophyll fluorescence was measured in the half-seed explants after 5th days culture on the media with (CIMA) or without (CIMB) antioxidants. Bars represents means ± standard deviations of three replications. Distinct letters denote statistically significant differences with Duncan’s tests. The half seed explants (Fig 1a) were cultured on the callus inducing (CIMA) media supplemented with the plant hormones 1.67 mg.l-1 BAP and 0.25 mg.l-1 GA3. Such combination of phytohormones has been successfully applied for regeneration of transformed cotyledonary node (OLHOFT et al., 2003; PAZ et al., 2004) and half- seed (PAZ et al., 2006) explants of different soybean varieties. During the first five days, the most of explants positively responded by producing of green chlorophyll. (Fig. 1b). The number of green explants varied from 18.3% (cv. Naya) to 55.9% (cv. Gallec) (Table 3). Besides, direct regeneration of shoots from cotyledonary explants and/or from shoot apical meristem was observed (Fig. 1b). Following five days, the explants were sub cultured on the shoot-inducing (SIM) medium (Fig. 1c). The calli and the shoots were appeared after 2-3 weeks culture on the SIM medium. The first larger shoots were excised and discarded. Treatment with BAP breaks down apical dominance and triggers adventitious shoot formation (WRIGHT et al., 1986). As was noticed by others (SAIRAM et al., 2003), only the callus induced from the nodal region gave rise to shoots. Healthy shoots (Fig. 1d) were excised, transferred to the shoot-elongation (SEM) medium. The efficiency of regeneration of cultivars was evaluated five weeks after subculture on the SIM medium. It was calculated as percentage of the number of explants producing at least one shoot to the total number of explant used. Data are given in Fig. 4. The best regeneration responses were observed for the cultivars Merlin (36.6%) and Gallec (37.7%) while the lowest was found for the cultivars Naya (5.7%) and Silensia (8.0%). The regeneration was clearly genotype dependent (p≤0,001) (Table 2). Based on the data obtained (Table 3), the response of the explants to the culture media for the first five days seems to define the regeneration potential. Generally, low regeneration potential is associated with sensitivity and strong plant stress responses to the in vitro manipulation (BENSON, Bereitgestellt von Slovenská poľnohospodárska knižnica | Heruntergeladen 17.01.20 13:55 UTC 8 Sojková, J. et al. 2000). However, histochemical staining of some parameters of stress (Fig. 2) did not reveal obvious differences between individual genotypes, probably because points on the surface layer of epidermal cells that are usually most damaged. We suppose that lower regeneration efficiencies achieved for some cultivars as Naya and Silensia might coincide rather with the composition of the regeneration media. Optimizing of the exogenous hormone levels in media might lead to increased regeneration efficiencies of these genotypes, albeit this would require much loads of time and other inputs thus are not usable for routine screenings. Nevertheless, the half-seed regeneration system appears to be suitable for regeneration of soybean plants from all tested genotypes. Table 3. Results from in vitro regeneration of soybean cultivars Number of responded explants No. Expl.a Green b [%] c Calli d [%]e Calli and shoots f [%]g Bohemians 103 30 29.1 69 67.0 24 34.8 Cardiff 111 46 41.4 91 82.0 36 39.6 Gallec 104 55 55.9 86 82.7 39 37.2 Merlin 106 50 47.2 88 83.0 39 44.4 Moravians 113 42 37.2 68 60.2 34 50.0 Naya 109 20 18.3 52 47.7 6 11.5 Silensia 136 28 20.6 68 50.0 11 16.2 a Total number of explants used in experiments b The number of green chlorophyll containing explants after 5th day culture on the CIMA medium c The number of green chlorophyll containing explants as a percentage of the total number of explants used d The number of explants producing calli e The number of callus-producing explants as a percentage of the total number of explants used. f The number of callus- and shoot -producing explants after 5th weeks culture on the media g The number of callus- and shoot -producing explants after 5th weeks culture on the media as a percentage of the number of callus-producing explants. Fig. 4. Regeneration efficiencies of soybean cultivars. Regeneration efficiency was calculated as percentage of the number of explants producing at least one shoot to the total number of explant used. Bars represents means ± standard deviations of three replications. Distinct letters denote statistically significant differences with Duncan’s tests. Bereitgestellt von Slovenská poľnohospodárska knižnica | Heruntergeladen 17.01.20 13:55 UTC Nova Biotechnologica et Chimica 15-1 (2016) 9 4. Conclusions In vitro regeneration potential of commercially important soybean cultivars Bohemians, Cardiff, Gallec, Merlin, Moravians, Naya and Silensia was studied. Half- seeds as an explant source were used. Within five weeks subculture on the regeneration media, shoots were generated from the explants of all cultivars. Adding the given antioxidants into the callus-induction medium had no significant effect on the cell regeneration. Regeneration efficiency was genotype dependent and varied between 5.7% and 37.7%. We concluded that the genotypes Naya and Silensia are likely to appear as recalcitrant for regeneration after transformation with Agrobacteria. On the other hand, the cultivars with the high regeneration potential such as Cardiff (32.6%), Merlin (36.6%) and Gallec (37.7%) appear to be more promising for further biotechnological applications via genetic transformations. Acknowledgment: This work was supported by the bilateral project SAV-PAV (2016-2018), by the Slovak Grant Agency VEGA 1/0061/15 and by the University Grant Agency UKF UGAVIII/35/16. References BARWALE, U. B., KERNS, H. R., WIDHOLM, J. M.: Plant-regeneration from callus-cultures of several soybean genotypes via embryogenesis and organogenesis. Planta, 167, 1986, 473-481. BENSON, E. E.: In vitro plant recalcitrance: An introduction. In Vitro Cell. Dev-Pl., 36, 2000, 141-148. BIRT, D.F., HENDRICH, S., ANTHONY, M., ALEKEL, D.L.: Soybeans and the prevention of chronic human disease. Soybeans: Improvement, Production and Uses. J. SPECHT, R. BOERMA, Eds. 3rd ed., American Society of Agronomy, Madison, WI, 2004, 1047–1117 BOHN, T., CUHRA, M., TRAAVIK, T., SANDEN, M., FAGAN, J., PRIMICERIO, R.: Compositional differences in soybeans on the market: Glyphosate accumulates in Roundup Ready GM soybeans. Food Chem., 153, 2014, 207-215. BOSZORADOVA, E., LIBANTOVA, J., MATUSIKOVA, I., POLONIOVA, Z., JOPCIK, M., BERENYI, M., MORAVCIKOVA, J.: Agrobacterium-mediated genetic transformation of economically important oilseed rape cultivars. Plant Cell Tiss. Org., 107, 2011, 317-323. DAN, Y.: Biological functions of antioxidants in plant transformation. In Vitro Cell. Dev-Pl., 44, 2008, 149-161. DEL RIO, L. A.: ROS and RNS in plant physiology: an overview. J. Exp. Bot., 66, 2015, 2827-2837. DEMIDCHIK, V.: Mechanisms of oxidative stress in plants: From classical chemistry to cell biology. Environ. Exp. Bot., 109, 2015, 212-228. DI, R., PURCELL, V., COLLINS, G. B., GHABRIAL, S. A.: Production of transgenic soybean lines expressing the bean pod mottle virus coat protein precursor gene. Plant Cell Rep., 15, 1996, 746-750. Bereitgestellt von Slovenská poľnohospodárska knižnica | Heruntergeladen 17.01.20 13:55 UTC 10 Sojková, J. et al. ISHIBASHI, Y., KODA, Y., ZHENG, S.-H., YUASA, T., IWAYA-INOUE, M.: Regulation of soybean seed germination through ethylene production in response to reactive oxygen species. Ann. Bot., 111, 2013, 95-102. ISHIMOTO, M., RAHMAN, S. M., HANAFY, M. S., KHALAFALLA, M. M., EL- SHEMY, H. A., NAKAMOTO, Y., KITA, Y., TAKANASHI, K., MATSUDA, F., MURANO, Y., FUNABASHI, T., MIYAGAWA, H.,WAKASA, K.: Evaluation of amino acid content and nutritional quality of transgenic soybean seeds with high- level tryptophan accumulation. Mol. Breeding, 25, 2010, 313-326. JANANI, C., KUMARI, B.D.: In vitro plant regeneration from cotyledonary node and half seed explants of Glycine max L. (JS335). Ann. Biol. Res., 4, 2013, 60-66. KIM, M.J., KIM, J. K., KIM, H. J., PAK, J. H., LEE, J.H., KIM, D.H., CHOI, H. K., JUNG, H. W., LEE, J.D., CHUNG, Y.S.,HA, S.H.: Genetic Modification of the Soybean to Enhance the beta-Carotene Content through Seed-Specific Expression. Plos One, 7, 2012. KUTA, D. D., TRIPATHI, L.: Agrobacterium-induced hypersensitive necrotic reaction in plant cells: a resistance response against Agrobacterium-mediated DNA transfer. Afr. J. Biotechnol., 4, 2005, 752-757. LIU, S.J., WEI, Z.M., HUANG, J.Q.: The effect of co-cultivation and selection parameters on Agrobacterium-mediated transformation of Chinese soybean varieties. Plant Cell Rep., 27, 2008, 489-498. MARNETT, L. J.: Oxyradicals and DNA damage. Carcinogenesis, 21, 2000, 361-370. OLHOFT, P. M., FLAGEL, L. E., DONOVAN, C. M., SOMERS, D. A.: Efficient soybean transformation using hygromycin B selection in the cotyledonary-node method. Planta, 216, 2003, 723-735. OLHOFT, P. M., LIN, K., GALBRAITH, J., NIELSEN, N. C., SOMERS, D. A.: The role of thiol compounds in increasing Agrobacterium-mediated transformation of soybean cotyledonary-node cells. Plant Cell Rep., 20, 2001, 731-737. OLHOFT, P. M., SOMERS, D. A.: L-cysteine increases Agrobacterium-mediated T- DNA delivery into soybean cotyledonary-node cells. Plant Cell Rep., 20, 2001, 706-711. OROZCO-CARDENAS, M. L., NARVAEZ-VASQUEZ, J.,RYAN, C. A.: Hydrogen peroxide acts as a second messenger for the induction of defense genes in tomato plants in response to wounding, systemin, and methyl jasmonate. Plant Cell, 13, 2001, 179-191. PAZ, M. M., MARTINEZ, J. C., KALVIG, A. B., FONGER, T. M., WANG, K.: Improved cotyledonary node method using an alternative explant derived from mature seed for efficient Agrobacterium-mediated soybean transformation. Plant Cell Rep., 25, 2006, 206-213. PAZ, M. M., SHOU, H. X., GUO, Z. B., ZHANG, Z. Y., BANERJEE, A. K., WANG, K.: Assessment of conditions affecting Agrobacterium-mediated soybean transformation using the cotyledonary node explant. Euphytica, 136, 2004, 167- 179. POMPELLA, A., MAELLARO, E., CASINI, A.F., COMPORTI, M.: Histochemical detection of lipid peroxidation in the liver of bromobenzene- poisoned mice. Am. J. Pathol., 129, 1987, 295–301. Bereitgestellt von Slovenská poľnohospodárska knižnica | Heruntergeladen 17.01.20 13:55 UTC Nova Biotechnologica et Chimica 15-1 (2016) 11 SAIRAM, R. V., FRANKLIN, G., HASSEL, R., SMITH, B., MEEKER, K., KASHIKAR, N., PARANI, M., AL ABED, D., ISMAIL, S., BERRY, K.,GOLDMAN, S. L.: A study on the effect of genotypes, plant growth regulators and sugars in promoting plant regeneration via organogenesis from soybean cotyledonary nodal callus. Plant Cell Tiss. Org., 75, 2003, 79-85. TAMAS, L., DUDIKOVA, J., DURCEKOVA, K., HALUGKOVA, L.U., HUTTOVA, J., MISTRIK, I., OLLE, M.: Alterations of the gene expression, lipid peroxidation, proline and thiol content along the barley root exposed to cadmium. J. Plant Physiol. 165, 2008, 1193–1203 VERMA, K., SAINI, R., RANI, A.: Recent advances in the regeneration and genetic transformation of soybean. J. Innov. Biol., 1, 2014, 015-026. WANG, G., XU, Y.: Hypocotyl-based Agrobacterium-mediated transformation of soybean (Glycine max) and application for RNA interference. Plant Cell Rep., 27, 2008, 1177-1184. WRIGHT, M. S., KOEHLER, S. M., HINCHEE, M. A., CARNES, M. G.: Plant- regeneration by organogenesis in Glycine-max. Plant Cell Rep., 5, 1986, 150-154 Received 23 March 2016 Accepted 5 May 2016 . Bereitgestellt von Slovenská poľnohospodárska knižnica | Heruntergeladen 17.01.20 13:55 UTC