Packing more vitamin D into tomatoes could help us get our daily dose

Embargoed until: Publicly released: 2022-05-24 01:00

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Tomatoes can be genetically modified to contain higher levels of vitamin D, according to researchers who say this could help reduce deficiency of the vitamin around the world. The researchers say we get the bulk of our vitamin D from our diet, but few foods contain enough. By editing a gene involved in converting provitamin D3 into cholesterol, they say the tomato keeps more of the provitamin which can be converted to vitamin D through UV exposure, or sunlight. The researchers say the vitamin D you can get from one of these genetically modified tomatoes is equivalent to two eggs or 28 grams of tuna.

News release

From: Springer Nature

Biotechnology: Tomatoes engineered to produce vitamin D (N&V)

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Tomatoes can be engineered to produce more provitamin D3 — a precursor to vitamin D3 — by blocking the action of an enzyme that normally converts this vitamin to cholesterol, according to a study published in Nature Plants. These tomatoes could represent a new dietary source of vitamin D3, with potential public health implications.

Vitamin D deficiency is a major global health issue that affects approximately one billion people worldwide and can lead to an increased risk of developing diseases such as cancer, Parkinson’s disease and dementia. Although humans can synthesize vitamin D3 on exposure to sunlight, most of this vitamin comes from our diets. However, dietary sources are limited, especially those from plants.

Cathie Martin and colleagues edited a gene in tomatoes that encodes an enzyme (7-dehydrocholesterol reductase) that normally converts provitamin D3 into cholesterol. By editing the gene, the authors were able to block this pathway, leading to the substantial accumulation of provitamin D3 in the tomatoes’ fruits and leaves, without affecting plant growth, development or yield. Provitamin D3 can then be converted to vitamin D3 by treatment with UV-B light, or can be used by the human body to synthesize vitamin D3 on UV-B exposure. The authors find that the amounts of provitamin D3 in one tomato fruit — if converted to vitamin D3 — would equal levels present in two medium-sized eggs or 28 grams of tuna. Eating the tomato fruits, they state, could help satisfy child and adult daily requirements for vitamin D3.

The authors conclude that this strategy could inspire further research into crop engineering to increase levels of vitamin D3 in plants.

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Journal/
conference: Nature Plants

Research:Paper

Organisation/s: Norwich Research Park, UK

Funder: This study was supported by the joint ERA CAPS Regulatome project: BBSRC BB/N005023/1 (A. Scarano, F.D. and C.M.); the Institute Strategic Programmes ‘Understanding and Exploiting Plant and Microbial Secondary Metabolism’ (BB/ J004596/1) and ‘Molecules from Nature’ (BB/P012523/1), CEPAMS Funding (Project CPM19), and a Proof of Concept Award from the High Value Compounds from Plants Network in Industrial Biotechnology and Bioenergy (POC-OCT17-04) from the UK Biotechnology and Biological Sciences Research Council (J.L., N.M.G., F.D., G.S., L.H., C.d.O.M. and C.M.), the European-funded COST ACTION FA1106, QualityFruit, which supported F.D. with an STSM award, and the European Union’s Horizon 2020 research and innovation programme through the TomGEM project under grant agreement number 679796 (A. Scarano and C.M.). A. Santino and A. Scarano were in part supported by CNR-DiSBA projectNutrAge (project number 7022) and the European-funded COST Action CA18111 (PlantEd, Genome editing in plants). F.D. was in part supported by BIOTECH-Cisget project from the Italian Ministry of Agriculture (MiPAAF) and by SMART-BREED project (A0375E0166, POR FESR LAZIO 2014 – 2020).

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