Tomatoes could be engineered to be sweeter without sacrificing size, study shows
Tomatoes could be engineered to be sweeter without sacrificing their size, research suggests.
Experts said that most consumers prefer sweeter tomatoes and higher sugar content increases the value of the tomato for the tomato processing industry.
However, it can be difficult to achieve both sweetness and size in tomato plants.
But a new study suggests that altering two genes can result in sweeter tomatoes, without their size or yield being compromised.
Chinese researchers compared cultivated and wild tomato species and identified two genes, SlCDPK27 and SlCDPK26, behind sugar accumulation in tomatoes.
Using the gene-editing tool known as Crispr, the scientists knocked out these genes in tomatoes and found that glucose and fructose levels increased by up to 30% in the fruit, without reducing weight or yield from the plants.
Although the gene-edited tomatoes produced fewer and lighter seeds, the seed health and germination rates were only minimally affected, the researchers noted.
Writing in the journal Nature, Sanwen Huang, from the Chinese Academy of Agricultural Sciences, and colleagues, said: “Together, these findings provide insight into the regulatory mechanisms controlling fruit sugar accumulation in tomato and offer opportunities to increase sugar content in large-fruited cultivars without sacrificing size and yield.”
They added that the findings provide a possible solution for improving sugar content without reduction in fruit yield for modern commercial varieties, “which are preferred by both consumers and producers, and Crispr-edited ‘sweetness-promoting’ tomatoes may be available to consumers in the near future”.
According to the researchers, during the domestication of tomatoes, breeders have prioritised fruit size, resulting in fruits that are now 10–100 times larger than their wild ancestor, but this has come at the expense of sweetness.
The scientists also found that the two genes they identified are found in a range of plant species, suggesting that the findings could potentially be applied to other crops.
In an accompanying News and Views article, also published in Nature, Amy Lanctot and Patrick Shih said that the “work represents an exciting step forward in the understanding of resource partitioning in the fruit, and its implications for crop improvement worldwide”.