Transcriptome and Metabolome Reveal the Molecular Mechanism of Barley Genotypes Underlying the Response to Low Nitrogen and Resupply

Increasing nitrogen use efficiency in agronomically important plants: An insight into gene characteristics on a genome-wide scale in barley

Nitrogen (N) is a critical element for plant growth and development. Hence, improving nitrogen use efficiency (NUE) is vital for reducing costs and the environmental impact of agricultural practices. Understanding the genetic control of N metabolism is crucial to improve NUE, especially in agronomically important plants, such as barley (Hordeum vulgare). Using bioinformatics and functional genomics tools, we identified and characterized sixteen barley nitrogen metabolism-related gene families (HvNMGs) on a genome-wide scale, analysing gene features and evolution. These genes, located on six of seven barley chromosomes, are highly conserved in plants (including barley, rice, and Arabidopsis), as shown by phylogenetic analysis. We further explored the evolutionary relationships of NMGs through a genome-to-genome synteny analysis, which indicated higher conservation of NMGs between barley and other monocots, suggesting that these orthologous pairs predate species divergence. Protein-protein interaction analyses revealed that all of the HvNMGs show interactions, mainly with each other. The H. vulgare miRNAs target sites (hvu-miR) prediction identified six hvu-miR in 4 HvNMGs (HvGABA-T2, HvALDH10-1, HvALDH10-2 and HvARGAH), indicating their potential involvement in stress responses. The expression patterns analysis of publicly available RNA-seq data revealed that HvNMGs are expressed in all developmental stages of barley, and they respond to different stress conditions, indicating their essential role in plant growth, development and stress response. The organ-specific expression analysis, conducted using qPCR, of HvNMGs revealed higher expression of HvNiR and HvNRs in the leaf and significantly higher expression of HvARGAH and HvALDH10 in the spike than in other tissues, showing that some of the genes may be particularly important in some tissues than others. This data provides a foundation for understanding HvNMG function and could be used to improve barley yield by enhancing NUE - an important goal for both crop productivity and environmental sustainability.

The response of nutrient cycle, microbial community abundance and metabolic function to nitrogen fertilizer in rhizosphere soil of Phellodendron chinense Schneid seedlings

Nitrogen (N) as an essential macronutrient affects the soil nutrient cycle, microbial community abundance, and metabolic function. However, the specific responses of microorganisms and metabolic functions in rhizosphere soil of Phellodendron chinense Schneid seedlings to N addition remain unclear. In this study, four treatments (CK, N5, N10 and N15) were conducted, and the soil physicochemical properties, enzyme activities, microbial community abundances and diversities, metabolism, and gene expressions were investigated in rhizosphere soil of P. chinense Schneid. The results showed that N addition significantly decreased rhizosphere soil pH, among which the effect of N10 treatment was better. N10 treatment significantly increased the contents of available phosphorus (AP), available potassium (AK), ammonium nitrogen (NH4+-N), nitrate nitrogen (NO3--N) and sucrase (SU) activity, as well as fungal diversity and the relative expression abundances of amoA and phoD genes in rhizosphere soil, but observably decreased the total phosphorus (TP) content, urease (UR) activity and bacterial diversity, among which the pH, soil organic matter (SOM), AP, NH4+-N and NO3--N were the main environmental factors for affecting rhizosphere soil microbial community structure based on RDA and correlation analyses. Meanwhile, N10 treatment notably enhanced the absolute abundances of the uracil, guanine, indole, prostaglandin F2α and γ-glutamylalanine, while reduced the contents of D-phenylalanine and phenylacetylglycine in rhizosphere soil of P. chinense Schneid seedlings. Furthermore, the soil available nutrients represented a significant correlation with soil metabolites and dominant microorganisms, suggesting that N10 addition effectively regulated microbial community abundance and metabolic functions by enhancing nutrient cycle in the rhizosphere soil of P. chinense Schneid seedlings.