Protein tyrosine sulfation, catalyzed by tyrosylprotein Sulfotransferase (TPST), is one of the most common protein posttranslational modifications. TPST catalyzes the transfer of the sulfuryl group from 3’-phosphoadenosine 5’-phosphosulfate (PAPS) to the hydroxyl group of tyrosine residue of various secreted and membrane-bound proteins that transit to the Golgi. Protein tyrosine sulfation is a key modulator of extracellular protein-protein interactions, and mediates many physiological processes, including coagulation, leukocyte adhesion, virus infection, chemokine signaling. At present, it remains much unknown about the mechanisms of TPST regulated biological functions. It is shown that the majority of target proteins surround more than one tyrosine near sulfation site, an indication that position and number of sulfated tyrosine residues on target protein may affect protein-protein interaction. It is also possible that neighboring tyrosine may affect the rate or specificity of other tyrosine sulfation in a protein. The goal of this research is to develop a GST fusion system to study the significance of the multiple tyrosine residues for protein sulfation. Using PST-TPST coupled enzyme assay and enzyme-linked immunosorbent assay previously developed in our lab to analyze activity of TPST toward specifically designed substrates/inhibitors. The significance of tyrosine residues on protein sulfation substrates was investigated by site-specific mutagenesis for TPST catalysis. The Km and Vmax of TPST values were 52 M and 0.016 mol/min/mg, respectively. Significant variation in Km values were observed when tyrosines around sulfation site were mutated. However, similar Vmax values were obtained as long as tyrosine 3 of the sulfation site remained intact. Interestingly, the phenomenon of that precipitation of TPST was induced by GST-PSGL-1 was discovered when the tyrosine 3 residue was substituted by a variety of other amino acid and in the presence of PAP. The inhibition kinetics constants toward PSGL-1 3F peptide as inhibitor gave Ki value as 0.171 M. This result strongly indicated that an inhibitor for EV-71 PB entry can be developed in the future base on the similar strategy. Structural analysis using known TPST structure and PSGL-1 is needed to more clearly describe the interaction between TPST and PSGL-1. The interesting protein sulfation substrates would be overexpressed and purified quickly with development of GST system, and then the relationship between TPST and substrates using novel analyzed method could be explored rapidly.