Structural basis for ligand-induced inactivation of protein tyrosine receptor type Z (PTPRZ): Physiological relevance of head-to-toe RPTP dimerization

Protein tyrosine phosphatase receptor type Z (PTPRZ) has two receptor isoforms (PTPRZ-A and -B) containing tandem PTP-D1 and -D2 domains intracellularly, with only D1 being active. Pleiotrophin (PTN) binding to the extracellular region of PTPRZ leads to the inactivation of PTPase, thereby inducing oligodendrocyte precursor cell (OPC) differentiation and myelination in the CNS. However, the mechanisms responsible for the ligand-induced inactivation of PTPRZ remain unclear. We herein revealed that the crystal structure of the intracellular region of PTPRZ (PTPRZ-ICR) showed the “head-to-toe”-type dimer conformation, with D2 masking the catalytic site of D1. Mass spectrometry (MS) revealed that PTPRZ-ICR proteins remained in monomer-dimer equilibrium in aqueous solution, and a substrate-derived inhibitory peptide or competitive inhibitor (SCB4380) specifically bound to the monomer form in a 1:1 stoichiometric ratio, supporting the “head-to-toe dimerization” model for inactivation. A D2 deletion (ΔD2) or dimer interface mutation (DDKK) disrupted dimer formation, while the binding of SCB4380 was maintained. Similar to wild-type PTPRZ-B, monomer-biased PTPRZ-B-ΔD2 and PTPRZ-B-DDKK mutants efficiently dephosphorylated p190RhoGAP at Tyr-1105 when co-expressed in BHK-21 cells. The catalytic activities of these mutants were not suppressed by a treatment with PTN, but were inhibited by the cell-permeable PTPase inhibitor NAZ2329. The PTN treatment did not enhance OPC differentiation in primary cultured glial cells prepared from ΔD2 or catalytically-inactive CS mutant knock-in mice. Our results indicate that PTN-induced PTPRZ inactivation is attained by dimer formation of the intracellular tandem PTP domains in the head-to-toe configuration, which is physiologically relevant to the control of OPC differentiation in vivo.