1ZCK
native structure prl-1 (ptp4a1)
Summary for 1ZCK
Entry DOI | 10.2210/pdb1zck/pdb |
Related | 1ZCL |
Descriptor | protein tyrosine phosphatase 4a1, ACETIC ACID (3 entities in total) |
Functional Keywords | prl-1 ptp4a1, hydrolase |
Biological source | Rattus norvegicus (Norway rat) |
Cellular location | Cell membrane (By similarity): Q78EG7 |
Total number of polymer chains | 3 |
Total formula weight | 53430.82 |
Authors | Sun, J.P.,Wang, W.Q.,Yang, H.,Liu, S.,Liang, F.,Fedorov, A.A.,Almo, S.C.,Zhang, Z.Y. (deposition date: 2005-04-12, release date: 2005-09-20, Last modification date: 2024-10-30) |
Primary citation | Sun, J.P.,Wang, W.Q.,Yang, H.,Liu, S.,Liang, F.,Fedorov, A.A.,Almo, S.C.,Zhang, Z.Y. Structure and Biochemical Properties of PRL-1, a Phosphatase Implicated in Cell Growth, Differentiation, and Tumor Invasion. Biochemistry, 44:12009-12021, 2005 Cited by PubMed Abstract: The PRL (phosphatase of regenerating liver) phosphatases constitute a novel class of small, prenylated phosphatases that are implicated in promoting cell growth, differentiation, and tumor invasion, and represent attractive targets for anticancer therapy. Here we describe the crystal structures of native PRL-1 as well as the catalytically inactive mutant PRL-1/C104S in complex with sulfate. PRL-1 exists as a trimer in the crystalline state, burying 1140 A2 of accessible surface area at each dimer interface. Trimerization creates a large, bipartite membrane-binding surface in which the exposed C-terminal basic residues could cooperate with the adjacent prenylation group to anchor PRL-1 on the acidic inner membrane. Structural and kinetic analyses place PRL-1 in the family of dual specificity phopsphatases with closest structural similarity to the Cdc14 phosphatase and provide a molecular basis for catalytic activation of the PRL phosphatases. Finally, native PRL-1 is crystallized in an oxidized form in which a disulfide is formed between the active site Cys104 and a neighboring residue Cys49, which blocks both substrate binding and catalysis. Biochemical studies in solution and in the cell support a potential regulatory role of this intramolecular disulfide bond formation in response to reactive oxygen species such as H2O2. PubMed: 16142898DOI: 10.1021/bi0509191 PDB entries with the same primary citation |
Experimental method | X-RAY DIFFRACTION (1.9 Å) |
Structure validation
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