Updated project metadata. Systemic lupus erythematosus (SLE) is a systemic and heterogeneous autoimmune disease for which its treatment and phosphorylation-dependent regulatory mechanism remain elusive. Here, we aim to explore the molecular mechanism of phosphorylation regulation for SLE. We employed high-throughput Phosphoproteomics of peripheral blood mononuclear cells (PBMCs) from 126 patients with SLE remission stage (SLE_S), 70 patients with SLE active stage (SLE_A), 160 patients with RA, and 135 healthy controls (HC). An independent cohort that included 60 SLE_S, 35 SLE_A, 50 RA and 40 HC was used to validate the phosphosites via parallel reaction monitoring (PRM). We revealed upregulated pathways involved in cell adhesion and migration in patients with SLE (SLE_S and SLE_A) compared with HCs and RA. Expression pattern clustering analysis revealed several specifically upregulated phosphosites, and the leukocyte transendothelial migration was specifically enriched in SLE_A. We predicted several key kinases including MAP3Ks, MAP2Ks, IKKB and TBK1, and found that upregulated kinase activity is associated with increased phosphorylation of VCL, TLN1 and VAPB by kinases-substrate network analysis. These phosphorylated proteins also regulate the pathways related to cell adhesion and migration, and which have not been implicated in previous studies of SLE. Moreover, we validated these phosphosites with the same trend as 4D-LFQ data, including LCP1 S5, TLN1 S1201, TLN1 S1225, VCL S275 and VCL S579. In summary, the present study elucidates the changes of phosphosites, kinases and pathways in SLE, and may provide potentially novel targets for further mechanism exploration.