Recent advancements in plant science have shed light on the StCDF1 gene's critical role in enhancing nitrogen use efficiency in potatoes, a key crop in global food security. Researchers, led by Salomé Prat from CRAG and in collaboration with Christian Bachem from the University of Wageningen, have discovered that StCDF1 not only regulates tuber development but also plays a pivotal role in nitrogen assimilation. This breakthrough, detailed in New Phytologist, could lead to the development of potato cultivars that are both high-yielding and more nitrogen-efficient.
The study reveals that StCDF1's influence extends beyond its known function in day-length-dependent tuberization to include the direct regulation of genes involved in nitrogen uptake. This dual functionality of StCDF1 was elucidated through advanced techniques such as DAP-seq, which identified StCDF1's binding to the promoter region of the Nitrate Reductase (StNR) gene, a crucial enzyme in nitrate reduction. The research highlights the unique genetic makeup of potatoes, which possess a single gene copy for StNR, unlike most plants. This genetic configuration allows potatoes to utilize nitrate more efficiently. Knock-down lines of StCDF1 showcased improved nitrogen utilization under limiting conditions, underscoring the gene's potential in developing climate-smart potato varieties.
Salomé Prat emphasized the dual role of StCDF1, stating, "The novelty of our research lies in uncovering StCDF1's dual role in regulating both tuberization and the nitrogen assimilation pathways." This discovery paves the way for breeding programs aimed at reducing chemical fertilizer dependence, marking a significant step towards sustainable agriculture. By leveraging genetic insights, the study not only advances our understanding of potato biology but also highlights the potential of plant science in ensuring food security amidst changing global conditions.
Source: Crag