Enhancement of the methionine content of seed proteins by the expression of a chimeric gene encoding a methionine-rich protein in transgenic plants

Altenbach, Susan B.; Pearson, Karen W.; Meeker, Gabrielle B.; Staraci, Lisa C.; Sun, Samuel S. M.

doi:10.1007/bf00027311

Cited by 147 publications

(68 citation statements)

References 28 publications

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“…However, there is currently public concern about the use of genetically engineered foods in contemporary agriculture, particularly when genes are from a nonplant source. During the past decade, several potential candidate genes have been targeted for the nutritional improvement of protein content in crops, namely: Brazil nut 2S albumin (13), AmA1 (Amaranth Albumin 1) (14), β-phaseoline (15), HS-7 zein (3), cruciferin (16), sunflower seed albumin (17), and S-rich zein (18). However, excepting AmA1 (14,19,20), introduction of these genes in target plants has often resulted in an increase in one of the amino acids at the expense of others, leading to an imbalance of the amino acid profile in transgenic crops.…”

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confidence: 99%

Next-generation protein-rich potato expressing the seed protein gene AmA1 is a result of proteome rebalancing in transgenic tuber

Chakraborty

Agrawal

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

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Protein deficiency is the most crucial factor that affects physical growth and development and that increases morbidity and mortality especially in developing countries. Efforts have been made to improve protein quality and quantity in crop plants but with limited success. Here, we report the development of transgenic potatoes with enhanced nutritive value by tuber-specific expression of a seed protein, AmA1 (Amaranth Albumin 1), in seven genotypic backgrounds suitable for cultivation in different agro-climatic regions. Analyses of the transgenic tubers revealed up to 60% increase in total protein content. In addition, the concentrations of several essential amino acids were increased significantly in transgenic tubers, which are otherwise limited in potato. Moreover, the transgenics also exhibited enhanced photosynthetic activity with a concomitant increase in total biomass. These results are striking because this genetic manipulation also resulted in a moderate increase in tuber yield. The comparative protein profiling suggests that the proteome rebalancing might cause increased protein content in transgenic tubers. Furthermore, the data on field performance and safety evaluation indicate that the transgenic potatoes are suitable for commercial cultivation. In vitro and in vivo studies on experimental animals demonstrate that the transgenic tubers are also safe for human consumption. Altogether, these results emphasize that the expression of AmA1 is a potential strategy for the nutritional improvement of food crops.allergenecity | essential amino acids | nutritional health

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confidence: 99%

Next-generation protein-rich potato expressing the seed protein gene AmA1 is a result of proteome rebalancing in transgenic tuber

Chakraborty

Agrawal

et al. 2010

Proc. Natl. Acad. Sci. U.S.A.

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“…Although the 2S albumins from Brazil nut and sunflower contain 18% methionine͞8% cysteine and 16% methionine͞8% cysteine, respectively, they have lower levels of other essential amino acids. Eventually, when introduced in target plants, they resulted in dramatic increase only in methionine, along with a significant decrease in cysteine content (25,26). This result reduces the usefulness of such proteins as a means of improving nutritional quality of recipient plants if they are deficient in any other essential amino acids.…”

Section: Discussionmentioning

confidence: 99%

Increased nutritive value of transgenic potato by expressing a nonallergenic seed albumin gene from Amaranthus hypochondriacus

Chakraborty

Chakraborty²,

Datta³

2000

Proceedings of the National Academy of Sciences

131

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Improvement of nutritive value of crop plants, in particular the amino acid composition, has been a major long-term goal of plant breeding programs. Toward this end, we reported earlier the cloning of the seed albumin gene AmA1 from Amaranthus hypochondriacus. The AmA1 protein is nonallergenic in nature and is rich in all essential amino acids, and the composition corresponds well with the World Health Organization standards for optimal human nutrition. In an attempt to improve the nutritional value of potato, the AmA1 coding sequence was successfully introduced and expressed in tuber-specific and constitutive manner. There was a striking increase in the growth and production of tubers in transgenic populations and also of the total protein content with an increase in most essential amino acids. The expressed protein was localized in the cytoplasm as well as in the vacuole of transgenic tubers. Thus we have been able to use a seed albumin gene with a well-balanced amino acid composition as a donor protein to develop a transgenic crop plant. The results document, in addition to successful nutritional improvement of potato tubers, the feasibility of genetically modifying other crop plants with novel seed protein composition.

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“…Importantly, the methionine was also of benefit to sheep due to the rumen stability of the added methionine-rich sink protein (White et al 2001). The Brazil nut 2S albumin has been expressed in a number of seeds including tobacco, canola, narbon bean and soya bean, with increases in total seed methionine of 30-100% when compared with wildtype (Altenbach et al 1989(Altenbach et al , 1992Muntz et al 1997;Tabe & Higgins 1998). The levels of seed methionine in the GM soya beans and narbon beans were predicted to be sufficient for optimal animal nutrition; however, the potential human allergenicity of the Brazil nut protein has prevented it from being used commercially.…”

Section: Improving the Essential Amino Acid Balance In Plant Proteinsmentioning

confidence: 99%

Genetic contributions to agricultural sustainability

Dennis

Ellis

Green

et al. 2007

Phil. Trans. R. Soc. B

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The current tools of enquiry into the structure and operation of the plant genome have provided us with an understanding of plant development and function far beyond the state of knowledge that we had previously. We know about key genetic controls repressing or stimulating the cascades of gene expression that move a plant through stages in its life cycle, facilitating the morphogenesis of vegetative and reproductive tissues and organs. The new technologies are enabling the identification of key gene activity responses to the range of biotic and abiotic challenges experienced by plants. In the past, plant breeders produced new varieties with changes in the phases of development, modifications of plant architecture and improved levels of tolerance and resistance to environmental and biotic challenges by identifying the required phenotypes in a few plants among the large numbers of plants in a breeding population. Now our increased knowledge and powerful gene sequence-based diagnostics provide plant breeders with more precise selection objectives and assays to operate in rationally planned crop improvement programmes. We can expect yield potential to increase and harvested product quality portfolios to better fit an increasing diversity of market requirements. The new genetics will connect agriculture to sectors beyond the food, feed and fibre industries; agri-business will contribute to public health and will provide high-value products to the pharmaceutical industry as well as to industries previously based on petroleum feedstocks and chemical modification processes.

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Enhancement of the methionine content of seed proteins by the expression of a chimeric gene encoding a methionine-rich protein in transgenic plants

Cited by 147 publications

References 28 publications

Next-generation protein-rich potato expressing the seed protein gene AmA1 is a result of proteome rebalancing in transgenic tuber

Next-generation protein-rich potato expressing the seed protein gene AmA1 is a result of proteome rebalancing in transgenic tuber

Increased nutritive value of transgenic potato by expressing a nonallergenic seed albumin gene from Amaranthus hypochondriacus

Genetic contributions to agricultural sustainability

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