Global climate change has intensified droughts and other extreme weather conditions, leading to serious declines in agricultural productivity. Genetically modified (GM) soybeans with drought tolerance have been developed to enhance crop resilience. Prior to commercialization, GM crops must undergo compositional equivalence assessments to confirm that no unintended compositional differences exist compared to their non-GM counterparts. In this study, we evaluated the nutritional and compositional equivalence of two drought-tolerant GM soybean lines (DIAT7 and DIAT15) compared to their non-GM parental line (Williams 82) and three reference cultivars (Kwangan, U13625, and U14511). Soybeans were cultivated under identical field conditions, and proximate components, amino acids, fatty acids, minerals, and antinutritional factors were analyzed using standard methods. Although several analytes exhibited statistically significant differences (p<0.05), all compositional values for DIAT7 and DIAT15 were within the natural variation ranges of the reference cultivated with GM, OECD (2012), and the AFSI Crop Composition Database (v10.1). The GM lines showed protein (36-37%), lipid (19-21%), and total dietary fiber (24-27%) contents similar to those of the reference cultivars. Amino acid profiles were dominated by glutamic acid and aspartic acid, whereas linoleic acid (42-51%) and oleic acid (29-36%) were the major fatty acids, consistent with conventional soybeans. The levels of minerals and antinutrients, including raffinose, stachyose, and phytic acid, were also comparable to the reference ranges. These findings demonstrate that the drought-tolerant GM soybeans DIAT7 and DIAT15 are compositionally and nutritionally equivalent to non-GM soybeans, supporting their substantial equivalence and providing a scientific basis for food and environmental safety evaluation.

In this study, conducted in living modified organism (LMO) isolation fields, we sought to develop environmental risk assessment procedures for identifying the potential effects on non-target above-ground insects and spiders within agroecosystems cultivated with vitamin A-enhanced transgenic soybean with tolerance to the herbicide glufosinate. To this end, we investigated insect/arachnid species diversities and population densities on vitamin A-enhanced transgenic soybean and non-GM soybean (Gwangan) grown in LMO quarantine areas of Kyungpook National University (Gunwi) and the National Institute of Agricultural Sciences (Jeonju). In total, 93,419 individual insects and arachnids, representing 65 families in 12 orders, were captured during the study. In Gunwi, totals of 17,110 and 17,627 individual insects and arachnids were collected from vitamin A-enhanced transgenic soybean and Gwangan, respectively, whereas in Jeonju, totals of 28,621 and 30,061 individuals were collected from vitamin A-enhanced transgenic soybean and Gwangan, respectively. Although we detected no significant differences among the population densities of insect pests, natural enemies, and other insects on vitamin A-enhanced transgenic soybean and Gwangan grown within the same field, the population densities of these insects were found to be higher in Jeonju than those in Gunwi. Throughout the study, analysis of variance indicated no significant differences (p<0.05) in insect/arachnid populations, and multivariate analysis indicated that the abundance and diversity of plant-dwelling insects were similar within the same fields.

This study was conducted to develop environmental risk assessments and biosafety guides for insect-resistant genetically modified rice in an LMO (Living Modified Organism) isolation field. In the LMO quarantine area of Kyungpook National University, the species diversities and population densities of non-target insects found on insect-resistant genetically modified rice (Bt-T), rice resistant to Cnaphalocrocis medinalis, and non-GM rice (Dongjin-byeo and Ilmi-byeo) were investigated. The Bt-T plants were, therefore, evaluated under field conditions to detect possible impacts on above ground insects and spiders. In 2016 and 2017, the study compared transgenic rice and two non-GM reference rice, namely Dongjin-byeo and Ilmi-byeo, at Gunwi. A total of 9,552 individuals from 51 families and 11 orders were collected from the LMO isolation field. From the three types of rice fields, a total of 3,042; 3,212; and 3,297 individuals from the Bt-T, Dongjin-byeo, and Ilmi-byeo were collected, respectively. There was no difference between the population densities of the non-target insect pests, natural enemies, and other insects on the Bt-T compared to non-GM rice. The data on insect species population densities were subjected to principal component analysis (PCA) without distinguishing between the three varieties, namely GM, non-GM, and reference cultivar, in all cultivation years. However, the PCA clearly separated the samples based on the cultivation years. These results suggest that insect species diversities and population densities during plant cultivation are determined by environmental factors (growing condition and seasons) rather than by genetic factors.

This study was carried out to develop of environmental risk assessments and the biosafety guide for Vitamin E enhanced transgenic soybean at LMO (Living Modified Organism) isolation field. In LMO quarantine area of National Institute of Agricultural Sciences, insect species diversities and population densities on vitamin E enhanced transgenic soybean and non-GM soybeans (Willams 82 and Seoritae) were investigated. A total of 17,717 individuals of 77 species from 8 orders were collected in LMO isolation field. In three type soybeans field, total of 5,250 individuals in Vitamin E enhanced transgenic soybean, 5,510 individuals in Willams 82, and 6,957 individuals in Seoritae were collected, respectively. There was no difference between the population densities of insect pests, natural enemies and other insects on Vitamin E enhanced transgenic soybean and Willams 82, while natural enemies density on Seoritae was higher than on Vitamin E enhanced transgenic soybean, but insect pests density on Vitamin E enhanced transgenic soybean was higher. These results provided the insects diversity for risk assessment survey of Vitamin E enhanced transgenic soybean and suggested that the guideline could be useful to detect LMO crops.

In order to assess the substantial equivalence of two varieties of genetically modified rice, herbicide-tolerant Ab rice and the insect-resistant Bt rice, to the non-GM Dongjin-byeo cultivar. We analyzed the compositions and contents of the proximate, amino acids, minerals, fatty acids, vitamins, and anti-nutrients in their unpolished grains using t-test (p<0.05). A comparison of fatty acids compositions showed that the levels of stearic acid and arachidonic acid in Ab rice and those of myristic, palmitic, oleic, linoleic, and gadoleic acid in Bt rice were different significantly from the corresponding levels in Dongjin-byeo. Vitamin content did not differ between Bt and Dongjin-byeo, but the content of vitamins B1, B7, and E in Ab rice differed from that in Dongjin-byeo. Iron content in Ab and Bt rice was 2 times higher than that in Dongjin-byeo, although it was within the reference range set by Codex. The amount of the anti-nutrient trypsin inhibitor was 0.1 TIU/mg in the unpolished grain of all three rice varieties examined. Of the 47 components analyzed, 17 were significantly different among the three rice varieties; however, most of these differences were within the Codex reference range for commercial rice. Overall, it was confirmed that both Bt and Ab rice are substantially equivalent to the Dongjin-byeo and other commercial varieties of rice.

The β-carotene biofortified transgenic rice was developed by transforming rice cv. Nakdongbyeo with phytoene synthase (Psy) and carotene desaturase (Crt I) genes isolated from Capsicum and Pantoea. The aim of this study was to perform molecular characterization of rice transformants of T5-T7 generation harboring Psy and Ctr I genes driven by endosperm specific globulin promoter for biosafety evaluation of β-carotene biofortified transgenic rice. The structure and sequence of T-DNA in the transformation vector and the insertion sites, flanking sequences and generational stability of inserted T-DNA in transgenic rice lines were analyzed. The transformation vector consisted of right border, MAR gene, carotenogenic genes unit, herbicide resistance selectable marker unit, MAR gene and left border in sequential order. T-DNA was introduced at the position of 30,363,938-30,363,973 bp of chromosome No. 2 by adaptor-ligation PCR. Stable integration of T-DNA and stable expression of bar gene was confirmed in T5 to T7 generations. It was also confirmed that the backbone DNA of transformation vector containing antibacterial gene was not present in the genome of β-carotene biofortified transgenic rice. HPLC analysis confirmed that carotenoids were consistently detected through T5-T7 generations.

Content of key nutrients and anti-nutrients of the insect-resistant transgenic rice (Btt12R) developed in Korea that contains a cryIIIA insecticidal gene was compared with those of its non-transgenic counterpart (Oryza sative L. cv. Nakdongbyeo). Grains of Btt12R, its parent cultivar, and two commercial rice plants (cv. Yeonganbyeo and Hwaseongbyeo) grown in the adjoining fields under the same environmental conditions and field management were used for this study. Among the analyzed 47 nutrients (8 proximates, 17 amino acids, 8 fatty acids, 9 minerals, and 5 vitamins) and two anti-nutrients (trypsin inhibitors and phytic acid), although the levels of 17 components differed between Nakdongbyeo and Btt12R, all of the measured values from Btt12R were within the ranges of values observed in the two typical Korean varieties and commercial rice provided by the OECD. These results confirm that the nutritional quality of rice grains was not affected by the insertion of the cryIIIA gene.