Function behind choreography: cytoskeletal, nuclear, and mechanical dynamics drive growth transition in root hair development

Fuente: PubMed "pollen"
Plant Cell. 2026 Jul 2;38(7):koag165. doi: 10.1093/plcell/koag165.ABSTRACTIn plants, polar cell growth is essential for processes such as root hair and pollen tube growth, but how it integrates with nuclear movement, cytoskeletal organization, and cell mechanics is not fully understood. We conducted high-resolution live imaging of Arabidopsis thaliana root hairs throughout their development using a microfluidic device. We identified 3 distinct stages--fast growth, slow growth, and early maturation--and quantified growth kinetics at high temporal resolution. The transition from fast to slow growth was consistent with cytoskeletal dynamics causing reduced tip growth and decreased nucleus-tip distance. Based on these observations, we developed a mathematical model linking cytoskeletal dynamics with tip growth and nuclear dynamics. Through genetic and pharmacological approaches, we were able to disrupt or trigger this transition, supporting the model and revealing the existence of essential crosstalk between actin filaments and microtubules. Additionally, vacuole dynamics, root hair diameter, and cell stiffness changed during the fast-to-slow transition, indicating a coordinated regulation of multiple subcellular systems. Together, these results connect nuclear, cytoskeletal, and mechanical dynamics during root hair development, offering an integrated view of the subcellular processes behind the control of polar cell growth in plants.PMID:42430653 | DOI:10.1093/plcell/koag165