Project description:Partial substitution of chemical fertilizer with green manure

Project description:Moderate Organic Fertilizer Substitution for Partial Chemical Fertilizer Improved Soil Carbon Sources Utilization and Bacterial Community Composition in Dryland Wheat Field Current year

Project description:long-term organic fertilizer

Project description:Nitrate is the limiting nitrogen nutrient enabling photosynthetic plants to support the conversion of inorganic elements to organic biomass, which sustains all lives. Plants evolved multifaceted nitrate responses to modulate global gene expression, metabolism and developmental programs. However, primary nitrate signaling mechanisms remained elusive. Using an ultrasensitive Ca2+ biosensor, unique nitrate-induced Ca2+ signaling was illuminated in Arabidopsis cells and plants. Integrative functional genomic screens, chemical genetics, genome-wide transcript sequencing, and analyses of nitrate-associated traits uncovered the surprising roles of Ca2+ sensor protein kinases (CPKs) in orchestrating diverse primary and long-term nitrate responses. Nitrate specifies CPK signaling to reprogram transcriptome and govern N-assimilation, metabolism, transport, hormones, shoot growth, and root system architecture. CPKs may be targeted to enhance nitrogen-use-efficiency, reduce fertilizer demands, and alleviate ecosystem pollution. 

Project description:Long-term different organic fertilizer treatment

Project description:long-term organic fertilizer for ITS

Project description:Short-term manure application alters microbiota

Project description:Bacterial community in soil amended with chemical fertilizer and organic fertilizer

Project description:The long-term application of organic manure superior to chemical fertilizer on aboveground yield and belowground fungal communities in an agricultural ecosystem

Project description:Long-term application of bio-organic fertilizer