For plant geneticists, some genes are double the trouble
When聽plant geneticists聽find a gene that improves crop yields, they want to try to insert that same change into other crops. But Cold Spring Harbor Laboratory Professor and HHMI Investigator聽Zachary Lippman聽cautions that just knowing what a single gene does is not enough. He discovered that it pays to know what other closely related genes might be lurking in the genome to block a hoped-for improvement.聽
In research reported in聽Nature Plants, Lippman, former postdoc Cao Xu (now at the Chinese Academy of Sciences in Beijing), and colleagues demonstrate how duplicated genes in plant genomes complicate a crop developer's plans. Gene duplications are common in plants. Many act as "back-up copies" of the original gene. But based on his team's surprising findings, Lippman says that having a great candidate for gene editing is not enough to predict the outcome of planned changes, "The lack of predictability in the context of a duplicate gene really needs to be an eye-opener for designing crop improvements."
The group studied the gene聽clv3. This gene produces a protein that limits the growth of developing plant tissues. Mutations in聽clv3聽have led to higher yields in many domestic plants. In tomatoes, for example, mutations in聽clv3聽are associated with larger fruits聽with more seed sections. Lippman's team introduced equivalent mutations into the聽clv3聽gene in tomato, tobacco, ground cherry, and petunia plants. All four plants are members of the聽Solanaceae聽family, also known as nightshades. Lippman and his colleagues expected to see similar results but what he found was intriguing.
In tobacco, the effects were dramatic, doubling the size of certain growth regions. This change was due to the plant's loss of the聽clv3聽back-up gene. In tomato, the duplicated gene partially buffers聽clv3聽mutations, so effects were more moderate. In ground cherry and petunia, mutating聽clv3聽had little effect. Both plants had聽clv3-like genes that compensated for the changes made by the researchers to the聽clv3听驳别苍别.听
To Lippman, the lesson is that optimizing crops through genome editing may require taking an inventory of duplicated genes. Crop developers need to understand how important genes were duplicated, deleted, and changed over evolutionary time. This allows scientists to develop more predictable crop improvements.
More information: Dynamic evolution of small signaling peptide compensation in plant stem cell control, Nature Plants (2022).
Journal information: Nature Plants
Provided by Cold Spring Harbor Laboratory