In the new study, researchers used genome editing to switch off the gene responsible for producing dihydroflavonol 4-reductase, an enzyme involved in a critical step just before anthocyanins are formed in red lettuce. Once this gene was disabled, the plants no longer produced their characteristic red pigmentation.

Further analysis of the lettuce revealed another important change. Levels of several other flavonoids increased, including quercetin. The findings suggest that blocking anthocyanin production redirected the plant’s biochemical activity toward the buildup of these other compounds within the flavonoid biosynthesis pathway.

No Major Impact on Plant Growth

Despite the significant changes in pigment and flavonoid composition, the modified lettuce showed no meaningful reduction in growth. This result suggests that it may be possible to alter the balance of flavonoids in lettuce by encouraging the accumulation of precursor compounds instead of anthocyanins, while still maintaining normal growth and productivity.

Although the researchers have not yet directly compared the modified plants with conventional green lettuce varieties, red lettuce is already known for its high level of polyphenol production. As a result, this strategy could offer a promising way to develop lettuce varieties with customized functional components.

The researchers also note that flavonoid production is highly sensitive to environmental conditions, including light intensity and temperature. Because plant factories allow growers to carefully control these factors, the findings may help support the development of specialized lettuce varieties optimized for indoor cultivation systems.

The research in the Ezura group is funded by the following grants: Program on Open Innovation Platform with Enterprises, Research Institute and Academia, Japan Science and Technology Agency (JSTOPERA, JPMJOP1851).