Alteration of Carotenoid Metabolic Machinery by β-Carotene Biofortification in Rice Grains

To increase nutritional values as dietary sources of provitamin A and health-promoting antioxidants in rice grains, carotenoids have been biofortified in a Golden Ricelike variety, the stPAC ( stPsy-2A-stCrtI ) rice. In both of non-transgenic (NT) and stPAC seeds, total chlorophylls and carotenoids...

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Published in:Journal of plant biology = Singmul Hakhoe chi 2019, 62(6), , pp.451-462
Main Authors: Ku, Hyung-Keun, Jeong, Ye Sol, You, Min Kyoung, Jung, Young Joo, Kim, Tae Jin, Lim, Sun-Hyung, Kim, Jae Kwang, Ha, Sun-Hwa
Format: Article
Language:English
Subjects:
Biomedical and Life Sciences
Carotene
Carotenoids
Chlorophyll
Feedback control
Gene expression
Globulins
Grain
Health promotion
Life Sciences
Metabolic pathways
Metabolism
Negative feedback
Nutritive value
Plant Breeding/Biotechnology
Plant Ecology
Plant Genetics and Genomics
Plant Sciences
Plant Systematics/Taxonomy/Biogeography
Research Article
Rice
Seeds
Transgenes
Transgenic plants
Zeaxanthin
β-Carotene
생물학
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Summary:To increase nutritional values as dietary sources of provitamin A and health-promoting antioxidants in rice grains, carotenoids have been biofortified in a Golden Ricelike variety, the stPAC ( stPsy-2A-stCrtI ) rice. In both of non-transgenic (NT) and stPAC seeds, total chlorophylls and carotenoids were gradually decreased during seed development while de novo biosynthesized carotenoids being comprised mainly of β-carotene, lutein and zeaxanthin were accumulated from early stage of 10 DAF and peaked at 20 DAF in stPAC seeds. The de novo production of carotenoids coincided with the high levels of transgene expression driven by the rice globulin gene promoter. Interestingly, expression levels of endogenous carotenoid metabolic pathway genes were the highest at 30 DAF in NT seeds whereas they were generally down-regulated in stPAC seeds, suggesting a negative feedback control mechanism of carotenoid metabolism by enhanced carotenoid production. The transgenic protein levels in stPAC seeds were not changed much during seed storage for up to 5 years, while carotenoid contents in the seeds were decreasing after 1 year of storage. The decrease in carotenoid contents was restored when the transgenic plants re-grown, supporting the reliability of transgenic pathways for carotenoid biofortification in rice grains. Thus, our results showed that transgene-driven biofortification of carotenoids was made and maintained over several transgenic generations with a possible negative feed-back control of endogenous carotenoid metabolism during seed development.
ISSN:1226-9239
1867-0725
DOI:10.1007/s12374-019-0480-9