Organization of F-Actin via Concerted Regulation of Kette by PTP61F and dAbl

We identify Kette, a key regulator of actin polymerization, as a substrate for Drosophila protein tyrosine phosphatase PTP61F, as well as for dAbl tyrosine kinase. We further show that dAbl is a direct substrate for PTP61F. Therefore, Kette phosphotyrosine levels are regulated both directly and indirectly by PTP61F. Kette and PTP61F genetically interact in the regulation of F-actin organization in pupal eye discs, suggesting that tyrosine phosphorylation is essential for the proper regulation of Kette-mediated actin dynamics. This hypothesis was confirmed by demonstrating the loss of Kette-mediated F-actin organization and lamella formation in S2 cells in a Kette Y482F mutant in which the dAbl phosphorylation site was eliminated. Our results establish for the first time that PTP61F and dAbl ensure proper actin organization through the coordinated and reversible tyrosine phosphorylation of Kette.The actin cytoskeleton is regulated as a function of development, cell motility, intracellular transport, and the cell cycle by the polymerization of G-actin to F-actin (34). Correct regulation of actin cytoskeletal dynamics is essential to numerous differentiating and cellular processes in the nervous system (9) and musculature (42), among others. Actin polymerization is regulated by a number of proteins, among which is human NCK-associated protein 1 (NAP-1 3, 4, 45]). It and its Drosophila orthologue, Kette (Hem in FlyBase), are critical components in both SCAR/WAVE and WASP complexes, which play essential roles in transducing Rac1 signals to initiate Arp2/3-dependent actin polymerization (6, 25, 40, 48). Murine NAP-1 interacts with NCK, an SH2-SH3 adaptor protein (4), and is essential for proper neuronal differentiation in the cortex (53). Neuronal differentiation and neural tube defects are observed in NAP-1 mutant mice, apparently due to reduced localization of WAVE1 to the cell membrane (53).In Drosophila, loss of kette activity specifically results in the accumulation of cytosolic F-actin (6). Kette protein associates with F-actin in the cytosol, but also at focal contact sites, where it apparently antagonizes SCAR/WAVE function and activates WASP-dependent actin polymerization (6). Despite its role in repressing SCAR/WAVE function, Kette serves to protect the complex from proteosome-mediated degradation and is critical to its intracellular localization (25). At the level of the organism, kette alleles affect axonal growth and pathfinding due to aberrant actin cytoskeleton formation, for example, altering crossing of the embryonic ventral midline by VUM neuron axons, as well as generating aberrant axonal projections in both motor and sensory neurons (21). Like mammalian NAP-1, Drosophila kette also interacts with the fly NCK orthologue, dreadlocks (dock) (21). Other evidence for the conserved interaction of Kette with signaling cascades is provided by the observation that kette mutant phenotypes are partially rescuable by overexpression of the small G protein Rac1 (21). The interaction of kette with dock suggests the possibility of tyrosine phosphorylation in the regulation of Kette activity, but no evidence supporting this hypothesis has been reported.Signaling by tyrosine phosphorylation in various metazoans controls numerous processes involved in cellular differentiation and proliferation. Many of the components regulating tyrosine phosphorylation have been identified and characterized using genetic, biochemical, molecular, and genomic sequence analyses (31). However, in contrast to the very well-characterized regulation of cellular processes by kinase-mediated tyrosine phosphorylation (15, 52), their regulation by dephosphorylation by protein tyrosine phosphatases (PTPs) has generally lagged behind. Although the functions of several receptor PTPs have been clearly defined as playing essential roles in axon guidance in both Drosophila (12, 23, 41, 47, 50) and mammals (44, 49), our understanding of nontransmembrane PTPs (NT-PTPs) is more limited. Only three of the eight putative Drosophila NT-PTPs have been characterized genetically. Corkscrew (Csw) acts as a downstream effector of various receptor protein tyrosine kinases (PTKs) and is essential for R7 photoreceptor development (35). PTP-enhancer of Ras1 has been characterized as an essential regulator antagonizing signaling mediated by Ras1, possibly through tyrosine dephosphorylation of mitogen-activated protein kinase (24, 36). More recently, it has been shown that PTP-meg participates in the establishment and maintenance of axon projections in the Drosophila brain (51). Other than these, the functions of Drosophila NT-PTPs remain largely unknown.PTP61F was originally identified as an NT-PTP that contains one phosphatase domain in the N-terminal region and five proline-rich motifs in the C-terminal tail (29). It is the Drosophila orthologue of mammalian PTP1B and T-cell PTP (TC-PTP) (1), which have been implicated in the regulation of signaling by both insulin (39) and JAK/STAT (33). Two PTP61F isoforms due to alternative splicing possess unique sequences at the C terminus, which determine either internal membrane-association (PTP61Fm) or nuclear localization (PTP61Fn) (29). To date, limited data suggest that PTP61F may participate in the downregulation of JAK/STAT signaling (2, 32), although the underlying mechanism remains unexplored. While PTP61F may recognize the adaptor proteins DOCK (10) and Abi (20) as potential substrates, the signaling pathways involving these interactions have not been clearly defined. In this study, we demonstrate for the first time that the regulation of Kette, and hence the localization and polymerization of the actin cytoskeleton, is achieved by reversible tyrosine phosphorylation under the control of both PTP61F and the PTK dAbl.