posted on 2023-09-08, 15:06authored byXiaoming Qin, Songlan Hao, Chengxiao Hu, Min Yu, Sergey Shabala, Qiling Tan, Songwei Wu, Shoujun Xu, Jingguo Sun, Xuecheng Sun
While molybdenum (Mo) application can improve phosphorus
(P) availability
to plants by changing P speciation in the rhizosphere, the mechanistic
basis of this process remains unclear. This work investigated the
impact of various combinations of Mo and P treatments on root morphology,
P and Mo uptake, and root transcriptome and metabolome. Mo application
significantly increased soybean biomass and the number of lateral
roots at both low (5 μmol) or normal (500 μmol) P levels
and significantly improved P concentration and accumulation in Normal
P treatment. Compared with the Normal P treatment, Low P significantly
increased the number of roots, root surface area, and root acid phosphatase
secretion. A total of 6811 Mo-responsive differentially expressed
genes and 135 differential metabolites were identified at two P levels.
At Low P, transcriptional changes significantly increased root synthesis
and secretion of succinic acid, methylmalonic acid, and other organic
acids as well as acid phosphatase, thereby increasing the conversion
of soil aluminum-bound P and organic P into available P. At Normal
P, Mo application increased P uptake mainly by increasing the number
of lateral roots. Thus, Mo helps crops adapt to different P levels
by regulating root anatomy and transcriptional and metabolic profiles
of their roots.