Characterization and comparison of transgenic Artemisia annua GYR and wild-type NON-GYR plants in an environmental release trial

The anti-malarial drug, artemisinin, is quite expensive as a result of its slow content in Artemisia annua. Recent investigations have suggested that genetic engineering of A. annua is a promising approach to improve the yield of artemisinin. In this study, the transgenic A. annua strain GYR, which...

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Published in:Genetics and molecular research 2016-08, Vol.15 (3)
Main Authors: Liu, H, Wu, G G, Wang, J B, Wu, X, Bai, L, Jiang, W, Lv, B B, Pan, A H, Jia, J W, Li, P, Zhao, K, Jiang, L X, Tang, X M
Format: Article
Language:English
Subjects:
Adaptation, Physiological - genetics
Antimalarials - isolation & purification
Antimalarials - metabolism
Artemisia annua - genetics
Artemisia annua - metabolism
Artemisinins - isolation & purification
Artemisinins - metabolism
Cold Temperature
Droughts
Gene Expression Regulation, Plant
Gene Flow
Genetic Engineering
Germination - genetics
Hot Temperature
Malondialdehyde - metabolism
Phenotype
Plant Leaves - genetics
Plant Leaves - metabolism
Plants, Genetically Modified
Proline - metabolism
Salinity
Stress, Physiological
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container_issue 3
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container_title Genetics and molecular research
container_volume 15
creator Liu, H
Wu, G G
Wang, J B
Wu, X
Bai, L
Jiang, W
Lv, B B
Pan, A H
Jia, J W
Li, P
Zhao, K
Jiang, L X
Tang, X M
description The anti-malarial drug, artemisinin, is quite expensive as a result of its slow content in Artemisia annua. Recent investigations have suggested that genetic engineering of A. annua is a promising approach to improve the yield of artemisinin. In this study, the transgenic A. annua strain GYR, which has high artemisinin content, was evaluated in an environmental release trial. First, GYR plants were compared with the wild-type variety NON-GYR, with regard to phenotypic characters (plant height, crown width, stem diameter, germination rate, leaf dry weight, 1000-seed weight, leave shape). Second, stress resistance in the two varieties (salt, drought, herbicide, and cold resistance) was evaluated under different experimental conditions. Finally, gene flow was estimated. The results indicated that there were significant differences in several agronomic traits (plant height, stem diameter, and leave dry weight) between the transgenic GYR and NON-GYR plants. Salt stress in transgenic and control plants was similar, except under high NaCl concentrations (1.6%, w/w). Leaf water, proline, and MDA content (increased significantly) were significantly different. Transgenic A. annua GYR plants did not grow better than NON-GYR plants with respect to drought and herbicide resistance. The two varieties maintained vitality through the winter. Third, gene flow was studied in an environmental risk trial for transgenic GYR. The maximum gene flow frequency was 2.5%, while the maximum gene flow distance was 24.4 m; gene flow was not detected at 29.2 m at any direction. Our findings may provide an opportunity for risk assessment in future commercialization of transgenic A. annua varieties.
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Recent investigations have suggested that genetic engineering of A. annua is a promising approach to improve the yield of artemisinin. In this study, the transgenic A. annua strain GYR, which has high artemisinin content, was evaluated in an environmental release trial. First, GYR plants were compared with the wild-type variety NON-GYR, with regard to phenotypic characters (plant height, crown width, stem diameter, germination rate, leaf dry weight, 1000-seed weight, leave shape). Second, stress resistance in the two varieties (salt, drought, herbicide, and cold resistance) was evaluated under different experimental conditions. Finally, gene flow was estimated. The results indicated that there were significant differences in several agronomic traits (plant height, stem diameter, and leave dry weight) between the transgenic GYR and NON-GYR plants. Salt stress in transgenic and control plants was similar, except under high NaCl concentrations (1.6%, w/w). Leaf water, proline, and MDA content (increased significantly) were significantly different. Transgenic A. annua GYR plants did not grow better than NON-GYR plants with respect to drought and herbicide resistance. The two varieties maintained vitality through the winter. Third, gene flow was studied in an environmental risk trial for transgenic GYR. The maximum gene flow frequency was 2.5%, while the maximum gene flow distance was 24.4 m; gene flow was not detected at 29.2 m at any direction. 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Leaf water, proline, and MDA content (increased significantly) were significantly different. Transgenic A. annua GYR plants did not grow better than NON-GYR plants with respect to drought and herbicide resistance. The two varieties maintained vitality through the winter. Third, gene flow was studied in an environmental risk trial for transgenic GYR. The maximum gene flow frequency was 2.5%, while the maximum gene flow distance was 24.4 m; gene flow was not detected at 29.2 m at any direction. 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Recent investigations have suggested that genetic engineering of A. annua is a promising approach to improve the yield of artemisinin. In this study, the transgenic A. annua strain GYR, which has high artemisinin content, was evaluated in an environmental release trial. First, GYR plants were compared with the wild-type variety NON-GYR, with regard to phenotypic characters (plant height, crown width, stem diameter, germination rate, leaf dry weight, 1000-seed weight, leave shape). Second, stress resistance in the two varieties (salt, drought, herbicide, and cold resistance) was evaluated under different experimental conditions. Finally, gene flow was estimated. The results indicated that there were significant differences in several agronomic traits (plant height, stem diameter, and leave dry weight) between the transgenic GYR and NON-GYR plants. Salt stress in transgenic and control plants was similar, except under high NaCl concentrations (1.6%, w/w). Leaf water, proline, and MDA content (increased significantly) were significantly different. Transgenic A. annua GYR plants did not grow better than NON-GYR plants with respect to drought and herbicide resistance. The two varieties maintained vitality through the winter. Third, gene flow was studied in an environmental risk trial for transgenic GYR. The maximum gene flow frequency was 2.5%, while the maximum gene flow distance was 24.4 m; gene flow was not detected at 29.2 m at any direction. Our findings may provide an opportunity for risk assessment in future commercialization of transgenic A. annua varieties.</abstract><cop>Brazil</cop><pmid>27706602</pmid><doi>10.4238/gmr.15038273</doi><oa>free_for_read</oa></addata></record>
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subjects Adaptation, Physiological - genetics
Antimalarials - isolation & purification
Antimalarials - metabolism
Artemisia annua - genetics
Artemisia annua - metabolism
Artemisinins - isolation & purification
Artemisinins - metabolism
Cold Temperature
Droughts
Gene Expression Regulation, Plant
Gene Flow
Genetic Engineering
Germination - genetics
Hot Temperature
Malondialdehyde - metabolism
Phenotype
Plant Leaves - genetics
Plant Leaves - metabolism
Plants, Genetically Modified
Proline - metabolism
Salinity
Stress, Physiological
title Characterization and comparison of transgenic Artemisia annua GYR and wild-type NON-GYR plants in an environmental release trial
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