Abstract
Receptor-like protein-tyrosine phosphatases (RPTPs) are involved in various aspects of cellular functions, such as proliferation, differentiation, survival, migration, and metabolism. A small number of RPTPs have been reported to regulate activities of some cellular proteins including receptor protein-tyrosine kinases (RPTKs). However, our understanding about the roles of individual RPTPs in the regulation of RPTKs is still limited. The R3 RPTP subfamily reportedly plays pivotal roles in the development of several tissues including the vascular and nervous systems. Here, we examined enzyme-substrate relationships between the four R3 RPTP subfamily members and 21 RPTK members selected from 14 RPTK subfamilies by using a mammalian two-hybrid system with substrate-trapping RPTP mutants. Among the 84 RPTP-RPTK combinations conceivable, we detected 30 positive interactions: 25 of the enzyme-substrate relationships were novel. We randomly chose several RPTKs assumed to be substrates for R3 RPTPs, and validated the results of this screen by in vitro dephosphorylation assays, and by cell-based assays involving overexpression and knock-down experiments. Because their functional relationships were verified without exception, it is probable that the RPTKs identified as potential substrates are actually physiological substrates for the R3 RPTPs. Interestingly, some RPTKs were recognized as substrates by all R3 members, but others were recognized by only one or a few members. The enzyme-substrate relationships identified in the present study will shed light on physiological roles of the R3 RPTP subfamily.
Highlights
Our understanding of the physiological relevance between receptor-like protein-tyrosine phosphatase (RPTP) and receptor protein-tyrosine kinase (RPTK) is limited
RPTKs are autophosphorylated without ligand binding when highly expressed in mammalian cells, which is a prerequisite for our two-hybrid screen
Our results suggest that the R3 RPTP subfamily members have similar but distinct substrate specificities toward several RPTKs: ROS and PDGFRa were recognized only by Ptprb; EGFR1, VEGFR1, and VEGFR2 only by Ptprh; FGFR1 and ERBB2 by Ptpro and Ptprb; RET, MET, and LTK by Ptpro, Ptprb and Ptprj; whereas EphA4, EphB2, and TYRO3 were recognized by all members
Summary
Our understanding of the physiological relevance between receptor-like protein-tyrosine phosphatase (RPTP) and receptor protein-tyrosine kinase (RPTK) is limited. We randomly chose several RPTKs assumed to be substrates for R3 RPTPs, and validated the results of this screen by in vitro dephosphorylation assays, and by cell-based assays involving overexpression and knockdown experiments. Because their functional relationships were verified without exception, it is probable that the RPTKs identified as potential substrates are physiological substrates for the R3 RPTPs. Interestingly, some RPTKs were recognized as substrates by all R3 members, but others were recognized by only one or a few members. The enzyme-substrate relationships identified in the present study will shed light on physiological roles of the R3 RPTP subfamily. The R3 members showed differences in substrate specificity toward individual RPTKs
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