Novel QTL Associated with Aerenchyma-Mediated Radial Oxygen Loss (ROL) in Rice ( L.) under Iron (II) Sulfide.

In rice, high radial oxygen loss (ROL) has been associated with the reduction in the activity of methanogens, therefore reducing the formation of methane (CH) due to the abundance in application of nitrogen (N)-rich fertilizers. In this study, we evaluated the root growth behavior and ROL rate of a doubled haploid (DH) population ( = 117) and parental lines 93-11 (P1, ) and Milyang352 (P2, ) in response to iron (II) sulfide (FeS). In addition, we performed a linkage mapping and quantitative trait locus (QTL) analysis on the same population for the target traits. The results of the phenotypic evaluation revealed that parental lines had distinctive root growth and ROL patterns, with 93-11 () and Milyang352 () showing low and high ROL rates, respectively. This was also reflected in their derived population, indicating that 93.2% of the DH lines exhibited a high ROL rate and about 6.8% had a low ROL pattern. Furthermore, the QTL and linkage map analysis detected two QTLs associated with the control of ROL and root area on chromosomes 2 (, 127 cM, logarithm of the odds (LOD) 3.04, phenotypic variation explained (PVE) 11.61%) and 8 (, 97 cM, LOD 4.394, PVE 15.95%), respectively. The positive additive effect (2.532) of indicates that the allele from 93-11 contributed to the observed phenotypic variation for ROL. The breakthrough is that the harbors genes proposed to be involved in stress signaling, defense response mechanisms, and transcriptional regulation, among others. The qPCR results revealed that the majority of genes harbored by the recorded a higher transcript accumulation level in Milyang352 over time compared to 93-11. Another set of genes exhibited a high transcript abundance in P1 compared to P2, while a few were differentially regulated between both parents. Therefore, and , genes encoding transcription factors (TFs), coupled with , and are suggested to play important roles in the positive regulation of ROL in rice. However, the recorded differential expression of and , and the decrease in , , and TF expression between parental lines proposes them as being involved in the control of oxygen flux level in rice roots.