Effect of the cauliflower Or transgene on carotenoid accumulation and chromoplast formation in transgenic potato tubers

Lopez, Alex B.; Eck, Joyce Van; Conlin, Brian J.; Paolillo, Dominick J.; O'Neill, J. J.; Li, Li

doi:10.1093/jxb/erm299

Cited by 226 publications

(177 citation statements)

References 42 publications

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“…This protects the stability of IbPSY protein and leads to carotenoid accumulation. The different expression manners of the Or gene have led to varied phenomena: changing both the content and the composition of carotenoids (Lopez et al, 2008), promoting the accumulation of β-carotene and other carotenoids (Lopez et al, 2008;Li et al, 2012), and increasing the total carotenoid content without affecting the composition of carotenoids (Goo et al, 2015;Berman et al, 2017). In our work, the overexpression of the IbOr gene from yellow-fleshed sweet potato cultivar Hoang Long in transgenic maize plants resulted in the increase of both total carotenoids (1.76-10.36-fold) and β-carotene (2.03-15.11-fold).…”

Section: Discussionmentioning

confidence: 99%

Overexpression of the IbOr gene from sweet potato (Ipomea batatas ‘Hoang Long’)in maize increases total carotenoid and β-carotene contents

Tran¹,

Ho²,

Nguyen³

2017

Turk J Biol

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Nutritional quality of most maize varieties is very low due to the lack of lysine and tryptophan and extremely low provitamin A carotenoids including β-carotene, α-carotene, and β-cryptoxanthin. In this study, we report the successful overexpression of the IbOr gene in H145 and H95 inbred maize lines under the control of maize seed-specific promoter globulin 1 (Glo1) for the purpose of improving β-carotene in maize. The results showed that the total carotenoid and β-carotene content of all analyzed transgenic maize plants were significantly higher than those of wild-type lines. For H145-IbOr transgenic maize, in the best line (H145-IbOr.10), the total carotenoid and β-carotene contents were increased up to 10.36-and 15.11-fold, respectively, compared to the wild type (H145-WT). In the case of H95-IbOr transgenic plants, 5.58-fold increase in total carotenoid and 7.63-fold increase in β-carotene were achieved in the H95-IbOr.6 line compared to nontransgenic plants (H95-WT). In all the transgenic plants derived from the wild-type maize line with less carotenoid content (H145-WT), the content of both total carotenoid and β-carotene was higher than in transgenic plants derived from the wild-type maize line having more carotenoid content (H95-WT). Our research is the first in successful overexpression of IbOr gene in maize.

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Section: Discussionmentioning

confidence: 99%

Overexpression of the IbOr gene from sweet potato (Ipomea batatas ‘Hoang Long’)in maize increases total carotenoid and β-carotene contents

Tran¹,

Ho²,

Nguyen³

2017

Turk J Biol

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“…Chromoplast biogenesis, therefore, can be part of a strategy to enhance pVA contents and their stability [51]. Expression of the cauliflower Or gene was investigated for carotenoid accumulation and stability in potato [51,63]. Transgenic potato tubers enhanced carotenoids and β-carotene, and continued accumulating them during long-term cold storage with induced formation of chromoplasts [63].…”

Section: Stability and Storage Of Enhanced Pro-vitamin A In Transgenimentioning

confidence: 99%

Transgenic Pro-Vitamin A Biofortified Crops for Improving Vitamin A Deficiency and Their Challenges

Lee¹

2017

TOASJ

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Vitamin A Deficiency (VAD) has been a public health problem among children in developing countries. To alleviate VAD, Vitamin A Supplementation (VAS), food fortification, biofortification and nutrition education have been implemented in various degrees of success with their own merits and limits. While VAS is the most widely utilized intervention in developing countries to ease the burden of VAD, some have raised questions on VAS' effectiveness. Biofortification, often touted as an effective alternative to VAS, has received significant attention. Among the available biofortification methods, adopting transgenic technology has not only facilitated rapid progress in science for enhanced pro-Vitamin A (pVA) levels in target crops, but drawn considerable skepticism in politics for safety issues. Additionally, VAD-afflicted target regions of transgenic pVA crops widely vary in their national stance on Genetically Modified (GM) products, which further complicates crop development and release. This paper briefly reviews VAS and its controversy which partly demanded shifts to food-based VAD interventions, and updates the current status of transgenic pVA crops. Also, this paper presents a framework to provide potential influencers for transgenic pVA crop development under politically challenging climates with GM products. The framework could be applicable to other transgenic micronutrient biofortification.

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“…The Or gene product is a protein, DnaJ which contains a cysteine-rich domain. It is interesting that the DnaJ transcription factor does not increase the level of carotenoids by stimulating endogenous biosynthesis, but by affecting the formation of isolated structures within the hromoplast in which carotenoids have been accumulated (Lu et al, 2006;Lopez et al, 2008;Sanghera et al, 2013).…”

Section: Genetic/metabolic Engineering Of Carotenoidsmentioning

confidence: 99%

Application of Plant Biotechnology Techniques in Antioxidant Production

Ivanović¹,

Milašević²,

Djurović³

et al. 2016

AgricultForest

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SUMMARYNowadays, antioxidant compounds are receiving increased attention in scholarly literature as well as in research. Antioxidants are a diverse group of compounds that can neutralize free radicals and thus help prevent diseases that are a consequence of oxidative stress. The most common antioxidant compounds are vitamins (A-carotenoids, C and E), thiols molecules (thioredoxins, glutathione), phenolic compounds (phenolic acids and flavonoids), enzymes and metal ions, as well as others. Plants have been shown to be an excellent source of antioxidant compounds, such as carotenoids, polyphenols, vitamins and betalains. Plant biotechnology uses the genetic engineering of agricultural crops as a means of producing foods rich in antioxidant nutrients, whilst plant cells and tissue culture techniques are used for the in vitro increment of antioxidant compounds in plant cells. There are numerous inspiring and promising reports about the possibilities of plant biotechnology that should provoke and encourage more research focused on antioxidant production from plants. The exogenous antioxidant molecules of important to human health (since endogenous antioxidants can be produced by the human cell itself) and the use of genetic engineering and plant cell culture techniques in antioxidant production in commonly used crops are presented in this paper.

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Effect of the cauliflower Or transgene on carotenoid accumulation and chromoplast formation in transgenic potato tubers

Cited by 226 publications

References 42 publications

Overexpression of the IbOr gene from sweet potato (Ipomea batatas ‘Hoang Long’)in maize increases total carotenoid and β-carotene contents

Overexpression of the IbOr gene from sweet potato (Ipomea batatas ‘Hoang Long’)in maize increases total carotenoid and β-carotene contents

Transgenic Pro-Vitamin A Biofortified Crops for Improving Vitamin A Deficiency and Their Challenges

Application of Plant Biotechnology Techniques in Antioxidant Production

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