AUTHOR=Lee Dong-Keun , Redillas Mark C. F. R. , Jung Harin , Choi Seowon , Kim Youn Shic , Kim Ju-Kon 

TITLE=A Nitrogen Molecular Sensing System, Comprised of the ALLANTOINASE and UREIDE PERMEASE 1 Genes, Can Be Used to Monitor N Status in Rice

JOURNAL=Frontiers in Plant Science

VOLUME=9

YEAR=2018

URL=https://www.frontiersin.org/journals/plant-science/articles/10.3389/fpls.2018.00444

DOI=10.3389/fpls.2018.00444

ISSN=1664-462X

ABSTRACT=<p>Nitrogen (N) is an essential nutrient for plant growth and development, but its concentration in the soil is often insufficient for optimal crop production. Consequently, improving N utilization in crops is considered as a major target in agricultural biotechnology. However, much remains to be learnt about crop N metabolism for application. In this study, we have developed a molecular sensor system to monitor the N status in rice (<italic>Oryza sativa</italic>). We first examined the role of the ureide, allantoin, which is catabolized into allantoin-derived metabolites and used as an N source under low N conditions. The expression levels of two genes involved in ureide metabolism, <italic>ALLANTOINASE</italic> (<italic>OsALN</italic>) and <italic>UREIDE PERMEASE 1</italic> (<italic>OsUPS1</italic>), were highly responsive to the N status. <italic>OsALN</italic> was rapidly up-regulated under low N conditions, whereas <italic>OsUPS1</italic> was up-regulated under high N conditions. Taking advantage of the responses of these two genes to N status, we generated transgenic rice plants harboring the molecular N sensors, <italic>proALN::ALN-LUC2</italic> and <italic>proUPS1::UPS1-LUC2</italic>, comprising the gene promoters driving expression of the luciferase reporter. We observed that expression of the transgenes mimicked transcriptional regulation of the endogenous <italic>OsALN</italic> and <italic>OsUPS1</italic> genes in response to exogenous N status. Importantly, the molecular N sensors showed similar levels of specificity to nitrate and ammonium, from which we infer their sensing abilities. Transgenic rice plants expressing the <italic>proUPS1::UPS1-LUC2</italic> sensor showed strong luminescence under high exogenous N conditions (&gt;1 mM), whereas transgenic plants expressing the <italic>proALN::ALN-LUC2</italic> sensor showed strong luminescence under low exogenous N conditions (&lt;0.1 mM). High exogenous N (&gt;1 mM) substantially increased internal ammonium and nitrate levels, whereas low exogenous N (&lt;0.1 mM) had no effect on internal ammonium and nitrate levels, indicating the luminescence signals of molecular sensors reflect internal N status in rice. Thus, <italic>proALN::ALN-LUC2</italic> and <italic>proUPS1::UPS1-LUC2</italic> represent N molecular sensors that operate over a physiological and developmental range in rice.</p>