AtPCS1 is constitutively expressed in the Arabidopsis. Its mRNA level is not enhanced by the pretreatment of plant with heavy metals. This implies that AtPCS1 could be controlled by post-translational modification; and protein phosphorylation is one of the essential modification mechanisms in the cell. From the amino acid sequence of AtPCS1, Thr49 was predicted to be a potential phosphorylation site. The three-dimensional structure of NsPCS was used as the template for the computer modeling of the N-terminal domain of PCS from Arabidopsis. It was found that the side chain of Arg183 was very close to the phosphate group of the phospho-Thr49, and interaction between this phosphorylated group and the Arg183 may form a functional conformation for the catalytic site of PCS. Pre-vious studies have shown that phosphorylation status may affect PCS activity. In this study, several site-directed mutants on Thr49 were performed including AtPCS1(T49A), AtPCS1(T49D) and AtPCS1(T49E). After expression of the mutant proteins, we examined the kinetic parameters of PCS mutants. The Kcat of mutant proteins T49A, T49D and T49E decreased to 23%, 7.6% and 10.2% of the wild type protein, respectively. On the other hand, the Km of T49A decreased to 69%, but T49D and T49E had 5.8-fold and 1.9-fold increase in Km. Apparently, when Thr49 was replaced by acidic amino acid, the substrate affinity and catalytic efficiency of PCS was inhibited. It was postulated that PCS activity might be controlled by reversible phosphorylation, and the conformation of the enzyme can be changed by the introduction of this phosphate group. This conformation change might facilitate the entrance of the substrate into the catalytic sites. In addition, to purify the endogenous PCS from the plant, we tried to overexpress AtPCS1 in Arabidopsis. After antibiotic selection and the molecular identification of AtPCS1 by PCR, semi-quantitative RT-PCR and IPCR, we might obtain the transgenic Arabidopsis producing larger amount of PCS for further studies of the protein phosphorylation of the endogenous PCS.