Plant roots change their growth pattern during ‘puberty’
Understanding how roots grow can help us develop plants that, for example, are more resistant to drought. Research uncovers how roots go through a puberty phase, which could have important implications for developing climate-resilient agriculture. Their work appears in Science.
Plants, like all living organisms, transition through various developmental stages, starting as a seed, becoming a shoot, and eventually a full-grown, fertile plant. They even go through a sort of ‘puberty’ during which a young shoot changes its growth patterns, which is vital for survival and adaptation to the environment. By altering the direction in which cells divide, plants can grow more in width than in height, or vice versa.
Between the first and third week of development, roots undergo a lot of changes. Researchers now provide molecular details on 'root puberty’. Their findings highlight the crucial role of SQUAMOSA PROMOTER BINDING-LIKE 13 (SPL13) in regulating oriented cell divisions, a process essential for proper root growth and morphology.
"Our research provides molecular insights into the age-dependent changes occurring in the root during this crucial phase," says the senior author. "We discovered that a change in gene expression of SPL transcription factors, particularly SPL13, is crucial for this transition by regulating the orientation of cell division."
The transition that results from SPL13 activity is characterized by distinct changes in the morphology and molecular profile of the roots, which are critical for the plant's overall development.
The author explains, “We provided advanced microscopy-based screening technology that allowed to screen for molecules that alter cell division orientation in cell cultures. By assessing the mode-of-action of the identified compounds, we could demonstrate that altering SPL13 production in the cells makes the root systems grow steeper and deeper.”
Changing expression levels of SPL13 even allowed the scientists to speed up or slow down root aging.
“Our research,” explains the senior author, “not only presents a previously unknown fundamental mechanism of plant development, but it also opens new avenues for improved crop yields and plant resilience in changing environmental conditions.”
As the global population continues to grow, optimizing plant growth and development will be crucial for food security. The importance of SPL transcription factors in plant biology highlights their potential applications in agriculture through changing root growth patterns, which may make crops more resilient to drought, for example.
By revealing the previously hidden complexity of root development, this study also identifies a gap in current plant research. Most studies use root samples that are one week old, but it is now clear that roots go through significant changes in morphology and gene expression, which means the way we look at root growth in lab conditions will have to be reconsidered.