Cryo-EM structure of plant urea transporter DUR3 reveals essential role of C-terminal domain in tetramer assembly and insights into proton-coupled transport

Nitrogen pollution, caused by the overuse of nitrogen-fertilizers such as urea in agricultural production, has become a serious problem that threatens both the environment and human health. Improving the nitrogen use efficiency of crops is an important approach to reduce fertilizer use. DUR3, a high-affinity urea transporter, enables plants to acquire urea from natural or agricultural soils with low urea concentrations and has been proposed as a promising target for engineering crops to improve nitrogen-fertilizer use efficiency. Despite extensive studies for more than 20 years, the structure, substrate recognition and transport mechanism of DUR3 have remained unknown. Here we report the cryo-EM structure of maize DUR3 (ZmDUR3) at 3.41 Å resolution. ZmDUR3 adopts an amino acid-polyamine-organocation (APC) superfamily fold and is structurally distinct from animal facilitative urea transporters. Our structure provides important insights into urea recognition by DUR3 and suggests that a pair of acidic residues is potentially involved in proton coupling during urea transport. Furthermore, our structural and functional studies indicate that DUR3 assembles into a tetramer and tetramer formation is important for its function. Our results pave the way for engineering plant DUR3 protein for applications in sustainable agricultural production.