Mob as tumor suppressor is activated by Hippo kinase for growth inhibition in Drosophila
2007; Springer Nature; Volume: 26; Issue: 7 Linguagem: Inglês
10.1038/sj.emboj.7601630
ISSN1460-2075
AutoresXiaomu Wei, Takeshi Shimizu, Zhi-Chun Lai,
Tópico(s)Wnt/β-catenin signaling in development and cancer
ResumoArticle8 March 2007free access Mob as tumor suppressor is activated by Hippo kinase for growth inhibition in Drosophila Xiaomu Wei Xiaomu Wei Intercollege Graduate Program in Genetics, The Pennsylvania State University, University Park, PA, USA Search for more papers by this author Takeshi Shimizu Takeshi Shimizu Department of Biochemistry and Molecular Biology, The Pennsylvania State University, University Park, PA, USA Search for more papers by this author Zhi-Chun Lai Corresponding Author Zhi-Chun Lai Intercollege Graduate Program in Genetics, The Pennsylvania State University, University Park, PA, USA Department of Biochemistry and Molecular Biology, The Pennsylvania State University, University Park, PA, USA Department of Biology, The Pennsylvania State University, University Park, PA, USA Search for more papers by this author Xiaomu Wei Xiaomu Wei Intercollege Graduate Program in Genetics, The Pennsylvania State University, University Park, PA, USA Search for more papers by this author Takeshi Shimizu Takeshi Shimizu Department of Biochemistry and Molecular Biology, The Pennsylvania State University, University Park, PA, USA Search for more papers by this author Zhi-Chun Lai Corresponding Author Zhi-Chun Lai Intercollege Graduate Program in Genetics, The Pennsylvania State University, University Park, PA, USA Department of Biochemistry and Molecular Biology, The Pennsylvania State University, University Park, PA, USA Department of Biology, The Pennsylvania State University, University Park, PA, USA Search for more papers by this author Author Information Xiaomu Wei1, Takeshi Shimizu2 and Zhi-Chun Lai 1,2,3 1Intercollege Graduate Program in Genetics, The Pennsylvania State University, University Park, PA, USA 2Department of Biochemistry and Molecular Biology, The Pennsylvania State University, University Park, PA, USA 3Department of Biology, The Pennsylvania State University, University Park, PA, USA *Corresponding author. Intercollege Graduate Program in Genetics, The Pennsylvania State University, 201 LSB, University Park, PA 16802, USA. Tel.: +1 814 863 0479; Fax: +1 814 863 1357; E-mail: [email protected] The EMBO Journal (2007)26:1772-1781https://doi.org/10.1038/sj.emboj.7601630 PDFDownload PDF of article text and main figures. ToolsAdd to favoritesDownload CitationsTrack CitationsPermissions ShareFacebookTwitterLinked InMendeleyWechatReddit Figures & Info Tissue growth and organ size are determined by coordinated cell proliferation and apoptosis in development. Recent studies have demonstrated that Hippo (Hpo) signaling plays a crucial role in coordinating these processes by restricting cell proliferation and promoting apoptosis. Here we provide evidence that the Mob as tumor suppressor protein, Mats, functions as a key component of the Hpo signaling pathway. We found that Mats associates with Hpo in a protein complex and is a target of the Hpo serine/threonine protein kinase. Mats phosphorylation by Hpo increases its affinity with Warts (Wts)/large tumor suppressor (Lats) serine/threonine protein kinase and ability to upregulate Wts catalytic activity to target downstream molecules such as Yorkie (Yki). Consistently, our epistatic analysis suggests that mats acts downstream of hpo. Coexpression analysis indicated that Mats can indeed potentiate Hpo-mediated growth inhibition in vivo. Our results support a model in which Mats is activated by Hpo through phosphorylation for growth inhibition, and this regulatory mechanism is conserved from flies to mammals. Introduction Tissue growth and organ size are determined by coordinated cell proliferation and apoptosis in development. Recent studies have identified a new growth-inhibitory tumor suppression pathway that coordinates cell proliferation and apoptosis during Drosophila development (Hipfner and Cohen, 2004; Edgar, 2006; Hariharan and Bilder, 2006). Two protein kinases Hippo (Hpo) (Harvey et al, 2003; Jia et al, 2003; Pantalacci et al, 2003; Udan et al, 2003; Wu et al, 2003) and Warts (Wts)/large tumor suppressor (Lats) (Justice et al, 1995; Xu et al, 1995), and a scaffold protein Salvador (Sav)/Shar-pei (Kango-Singh et al, 2002; Tapon et al, 2002), are key components of this pathway. Moreover, two FERM-domain proteins, Merlin (Mer) and Expanded (Ex), function upstream of Hpo (Hamaratoglu et al, 2006), and Mob as tumor suppressor (Mats), associates with Wts to stimulate the catalytic activity of the Wts protein kinase (Lai et al, 2005). Recently, both putative receptor and ligand that function further upstream of, or in parallel with, Hpo signaling have been identified (reviewed in Hariharan, 2006). A major signal output of this growth inhibitory pathway is to inactivate a transcription coactivator Yorkie (Yki) via phosphorylation by Wts kinase (Huang et al, 2005). In addition to Cyclin E and Drosophila inhibitor of apoptosis 1 (diap1), the bantam microRNA is also found to be a target of the Hpo pathway (Nolo et al, 2006; Thompson and Cohen, 2006). Most components in this emerging signaling pathway are conserved from yeast to flies and humans, suggesting that this pathway plays a fundamental role in cellular regulation. The function of Mob proteins has been better studied in yeast, Drosophila and mammalian cells, which revealed a conserved property of Mob proteins as a binding partner as well as a coactivator of protein kinases of the Ndr (nuclear Dbf2-related) family (Hergovich et al, 2006b). As stated above, Drosophila Mats/dMob1 is required for mediating Hpo signaling by regulating Wts kinase activity in growth inhibition and tumor suppression (Lai et al, 2005). All four Drosophila mob genes dMob1–4 genetically interact with trc (tricornered) (He et al, 2005a), the fly Ndr homolog important for maintaining integrity of epidermal outgrowths and regulating dentritic tiling and branching (Emoto et al, 2004; He et al, 2005b). In the budding yeast Saccharomyces cerevisiae, Mob1 binds to and activates Dbf2/Dbf20 protein kinases for controlling mitotic exit and cytokinesis (Komarnitsky et al, 1998; Lee et al, 2001; Mah et al, 2001). Similarly, Mob1 is required for the activation of Sid2, an Ndr family kinase in the fission yeast Schizosaccharomyces pombe essential for cytokinesis (Hou et al, 2000, 2004). In human, hLats1 preferentially interacts with hMob1/hMats, but not hMob2 protein, and appeared to be required for promoting mitotic exit (Bothos et al, 2005), as well as cytokinesis (Yang et al, 2004). Importantly, the function of Mob proteins has been highly conserved in evolution. For instance, the human Mob1A/Mats1 protein has been shown to act as a kinase activator and can rescue the lethality and tumor phenotypes of Drosophila mats mutants (Lai et al, 2005). Structural analysis of a human Mob1 protein, Mob1A/Mats1, revealed several important features of Mob family proteins (Stavridi et al, 2003). One is that several highly conserved residues are responsible for generating an atypical Cys2-His2 zinc-binding site, which is predicted to contribute to the stability of the Mob protein. Another striking feature is that there is a flat surface rich in acidic residues on one side of the protein. This property provides the structural basis for a Mob protein to interact with its partner, such as Ndr family kinases through electrostatic forces. Indeed, a 65-amino-acid region rich in basic residues exists in the N-terminal side of the kinase domain of Ndr family kinases, and alterations in the basic residues can prevent the kinases from binding to Mob proteins (Bichsel et al, 2004; Bothos et al, 2005; Hergovich et al, 2006b). Finally, hMob1A adopts a globular structure involving residues throughout the polypeptide. Mob proteins are small and usually do not carry any other structural motifs other than the Mob domain. Although previous studies suggest that Ndr family kinases can be activated by upstream regulators such as Cdc15, Hpo and Mst kinases via phosphorylation in yeast, flies or human cells (Lee et al, 2001; Mah et al, 2001; Wu et al, 2003; Hou et al, 2004; Chan et al, 2005; Hergovich et al, 2006b), very little is known about how Mob is regulated. Studies carried out in yeast and mammalian cells suggested that Mob proteins may be regulated through phosphorylation. For instance, yeast Mob1 was shown to be essential for the phosphorylation of Dbf2 by an upstream protein kinase Cdc15 and Mob1 itself was also phosphorylated by Cdc15 (Mah et al, 2001). However, the functional significance of this modification has not been elucidated. Work on human Mob1A/Mats1 also suggested that phosphorylation might provide a mechanism for regulating hMob1A activity (Bichsel et al, 2004). In this study, we have tested a hypothesis that Mats is directly activated by Hpo kinase to regulate Wts kinase activity for growth inhibition and tumor suppression. Using the Drosophila system, we found that Mats can be complexed with Hpo and is a target of the Hpo protein kinase. Similarly, human Mats1 is also a target protein of mammalian Mst kinases. Mats phosphorylation by Hpo increases its affinity with Wts protein kinase and ability to increase Wts activity to target Yki. Moreover, our epistatic analysis suggested that mats acts downstream of hpo. Genetic analysis indicated that Mats functions together with Hpo for mediating growth inhibition of developing organs. Therefore, the Mob as tumor suppressor protein, Mats, functions as a critical component of the Hpo signaling pathway. Our results support a model in which Mats is activated by Hpo through phosphorylation for growth inhibition, and this regulatory mechanism is conserved from flies to mammals. Results Genetic interactions between mats, hpo, wts and sav We have previously shown that Mats functions as a coactivator of the Wts protein kinase to negatively regulate tissue growth (Lai et al, 2005). To further test the idea that Mats is a key component of the Hpo signaling pathway, we carried out genetic analysis using an in vivo assay in which a small-eye phenotype was induced by overexpression of a full-length Hpo or an N-terminal fragment of Hpo (HpoN), a constitutively activated form of Hpo (Jia et al, 2003; Udan et al, 2003) (Figure 1B and C, respectively). A wild-type eye is shown in Figure 1A for comparison. Whereas mats overexpression did not cause any morphological defects in the eye (Figure 1E; Lai et al, 2005), the Hpo- and HpoN-induced small-eye phenotype was strongly enhanced by coexpression with mats (Figure 1F and G), suggesting that Mats and Hpo synergistically interact to restrict tissue growth. Overexpression of a dominant-negative form of Hpo, HpoC (C-terminal fragment of Hpo) (Jia et al, 2003), did not cause obvious defects in the eye (Figure 1D). Similarly, flies that expressed both Mats and HpoC exhibited a normal eye phenotype (Figure 1H). Figure 1.Genetic interactions between Hpo pathway components hpo, sav, wts and mats. Scanning electron microscopy (SEM) images of adult compound eyes are shown. (A) Wild type. (B) In ey-Gal4/UAS-hpo flies, overexpression of Hpo in the developing eye reduced eye size. (C) An N-terminal fragment of Hpo (HpoN, a constitutively active form) in ey-Gal4/UAS-hpoN flies can also reduce eye size. (D) Overexpression of a C-terminal fragment of Hpo (HpoC, a putative dominant-negative form) in ey-Gal4/UAS-hpoC flies had no obvious effect on eye morphology. (E) The eye of ey-Gal4/UAS-mats flies was morphologically normal. Coexpression of Mats with Hpo in the eye of ey-Gal4/UAS-hpo; +/UAS-mats flies (F) or HpoN in ey-Gal4/UAS-hpoN; +/UAS-mats flies (G) markedly enhanced the small eye phenotype so that the eye became much smaller or abolished. (H) Coexpression of Mats with HpoC in ey-Gal4/UAS-hpoC; +/UAS-mats flies did not cause any obvious defect in the eye. (I) Overexpression of Wts in ey-Gal4/UAS-Myc-wts flies by using a strong transgenic line 6R reduced eye size and caused the eye to have a cone-like shape. Coexpression of wts with hpo in ey-Gal4/UAS-Myc-wts UAS-hpo flies (J) or hpoN in ey-Gal4/UAS-Myc-wts UAS-hpoN flies (K) completely abolished eye development. In contrast, the small and cone-like eye phenotypes induced by Wts were suppressed by HpoC coexpression in ey-Gal4/UAS-Myc-wts UAS-hpoC flies (L) or by reduction of endogenous activity of hpo in ey-Gal4/UAS-Myc-wts; +/hpoBF33 flies or sav in ey-Gal4/UAS-Myc-wts; +/sav3 flies (M, N, respectively). (O) Overexpression of Sav in ey-Gal4/UAS-HA-sav flies did not disrupt eye formation. However, Sav was able to enhance the small eye phenotype caused by Wts in ey-Gal4/UAS-Myc-wts UAS-HA-sav flies (P). Anterior is to the left in all panels. Download figure Download PowerPoint Genetic interactions between wts, hpo and sav were also examined using the eye system. Whereas overexpression of Wts in developing eye using a strong P[UAS-myc-wts]6R transgenic line significantly reduced the eye size and caused a cone-eye phenotype (Figure 1I), coexpression of Wts with Hpo or HpoN abolished eye development (Figure 1J and K, respectively). On the other hand, Wts-induced small cone-eye phenotype was suppressed by HpoC coexpression (Figure 1L), as well as by the reduction of the endogenous hpo or sav function (Figure 1M and N, respectively). Although overexpression of Sav in a wild-type background did not cause any morphological defect in the eye (Figure 1O), Wts-induced small-eye phenotype can be further enhanced by Sav coexpression (Figure 1P). Altogether, these results are consistent with a previously established model in which Wts functions downstream of Hpo and Sav to control tissue size. Epistatic analysis suggests that mats acts downstream of hpo To investigate epistatic relationship between mats and hpo, mats mutant cells that simultaneously overexpressed hpo were generated using the MARCM technique. As shown previously, loss of mats function in mosaic tissues such as larval eye discs caused tissue overgrowth (Figure 2B; Lai et al, 2005), compared to eye discs containing wild-type clones (Figure 2A). In contrast, overexpression of hpo in MARCM clones was sufficient to inhibit tissue growth (Figure 2C). Cells overexpressing hpo in the absence of endogenous mats function exhibited tissue overgrowth phenotype similar to that of mats single mutant (compare Figure 2D with B). Therefore, mats is epistatic to hpo and may act downstream of hpo. In another epistatic analysis, hpoN was expressed in all cells posterior to the morphogenetic furrow in the developing eye to induce apoptosis (Figure 2E). Using this assay, we found that the ability of hpoN to promote apoptosis was mostly dependent on mats (Figure 2F–H). By counting the number of TUNEL-positive spots in the mosaic larval eye discs (n=7), the percentages of apoptotic cells in mats wild-type and mutant tissues were estimated. Over 85% of the apoptotic cells were identified in mats wild-type tissues, whereas much fewer apoptotic cells (15%) were detected in mats mutant tissues that were about of the same size as neighboring wild-type areas. The fact that residual apoptosis could still be induced by Hpo in the absence of mats indicates that Hpo could act through other targets in addition to Mats to induce apoptosis. These results are consistent with the idea that mats functions downstream of hpo. Figure 2.mats is epistatic to hpo. Third instar larval eye imaginal discs are shown. Clones in mosaic eye discs were positively marked by GFP (green) in (A–D) using the MARCM method (Lee and Luo, 1999), and mats mutant clones were marked by the absence of β-galactosidase (green) in (F–H). (A) An eye disc that contains GFP-labeled wild-type MARCM clones is shown as a control. The genotype is w ey-FLP UAS-GFP/+; Tub-Gal4 FRT82B Tub-Gal80/FRT82B P[w+]90E. (B) An eye disc that contains GFP-labeled mats mutant MARCM clones exhibited an overgrowth phenotype. The genotype is w ey-FLP UAS-GFP/+; Tub-Gal4 FRT82B Tub-Gal80/FRT82B matse235. (C) Overexpression of Hpo in wild-type MARCM clones markedly inhibited tissue growth. The genotype is w ey-FLP UAS-GFP/+; UAS-hpo/+; Tub-Gal4 FRT82B Tub-Gal80/FRT82B P[w+]90E. (D) Loss of mats function effectively suppressed the growth inhibitory effect of Hpo. The genotype is w ey-FLP UAS-GFP/+; +/UAS-hpo; Tub-Gal4 FRT82B Tub-Gal80/FRT82B matse235. (E) GMR-Gal4 UAS-hpoN/+ and (F–H) w ey-FLP/+; +/GMR-Gal4 UAS-hpoN; FRT82B arm-lacZ/FRT82B matse235 eye discs were used for TUNEL staining of apoptotic cells (red). When driven by GMR-Gal4, HpoN was sufficient to cause apoptosis in the region posterior to the morphogenetic furrow (MF) in eye discs (E), and this HpoN-induced apoptosis occurred mostly in cells that were wild type for mats (F–H). Anterior is to the left in (A–D) and up-left in (E–H). Yellow arrows identify the morphogenetic furrow. Download figure Download PowerPoint Mats is a substrate of Hpo protein kinase in vitro In S. cerevisiae, a Mob family protein Mob1 acts downstream of the yeast homolog of Hpo protein kinase Cdc15 and is required for the function of Dbf2 protein kinase, the yeast homolog of Wts/Lats proteins (Lee et al, 2001; Mah et al, 2001). In addition to phosphorylating Dbf2 to activate its Mob1-dependent kinase activity, Cdc15 also phosphorylates Mob1, suggesting that Mob1 might be directly regulated by Cdc15 kinase (Mah et al, 2001). Based on the data from yeast and Drosophila, we hypothesized that Mats is directly regulated by Hpo kinase via phosphorylation. To test this hypothesis, Flag-tagged Hpo kinase protein was expressed in transiently transfected fly S2 cells or human embryonic kidney (HEK) 293T cells, and immunoprecipitated for analysis of its catalytic activity. Bacterially produced GST-Mats or GST proteins were used as substrates. In the presence of [γ-32P]ATP, substantial incorporation of 32P into GST-Mats was observed following incubation with Hpo protein (Figure 3A, lane 3). Mats phosphorylation was unlikely to be caused by any other contaminating kinases because Mats was not phosphorylated when HpoKD protein was used (Figure 3A, lane 4). GST served as a negative control (Figure 3A, lane 2). Interestingly, Sav did not appear to facilitate Hpo to phosphorylate Mats although it slightly increased Hpo's activity to autophosphorylate (Figure 3A, compare lane 5 with lane 3). Sav has been shown to be able to facilitate Hpo to phosphorylate Wts (Wu et al, 2003). Thus, Hpo may use a different mechanism to target Mats. Moreover, we found that Hpo phosphorylated human Mats1 (Figure 3B), and a rat Hpo ortholog Mst2 phosphorylated not only hMats1 (data not shown), but also fly Mats (Figure 3C). These results indicate that Mats is a target of Hpo/Mst, and the activity of Hpo/Mst kinases to phosphorylate Mats proteins is evolutionarily conserved. Figure 3.Mats associates with Hpo and is phosphorylated by Hpo protein kinase. (A) Hpo specifically phosphorylates Mats in vitro. pAc-hpo-Flag, pAc-hpoKD-Flag and pAc-sav-HA were transfected into S2 cells as indicated. Lysates of transfected cells were used for Western blot (WB) to show the inputs (middle two panels). Anti-Flag antibody was used to immunoprecipitate (IP) Hpo-Flag or HpoKD-Flag proteins for an in vitro kinase assay, in which GST-Mats or GST proteins were used as substrates (the bottom panel; CB: Coomassie blue staining). Hpo autophosphorylation and Mats phosphorylation by Hpo/HpoKD are shown in the top panel. (B) GST was not a substrate of Hpo kinase (lane 1). Hpo (lane 2) but not HpoKD (lane 3) can phosphorylate human Mats1 in vitro. (C) A rat Hpo ortholog, Mst2 kinase, can phosphorylate GST-Mats (lane 3) but not GST (lane 2) in vitro. Like Hpo, Mst2 mediates autophosphorylation (lanes 1–3). (D) In an in vitro pull-down assay, Mats was shown to associate with Hpo. Bacterially produced GST-Mats (lanes 1 and 3) or GST (lane 2) proteins were tested for their ability to interact with Hpo-Flag (lanes 2 and 3) produced in transfected S2 cells. (E) Human Mats1 was co-immunoprecipitated with the endogenous human Mst1. pCMV-hMats1 and pCMV-GFP were transfected into HEK293T cells as indicated. Inputs of hMats1 (lane 2), GFP (lane 3) and hMst1 (lanes 1–3) proteins are shown in panels on the left. Immunoprecipitations were carried out using anti-hMst1 antibodies to isolate the endogenous hMst1 protein (lanes 4-6, the bottom-right panel), and hMats1 (lane 5) but not GFP (lane 6) was co-immunoiprecipitated (top two panels on the right). Download figure Download PowerPoint Hpo and Mats associate to form a protein complex To address whether Mats directly interacts with the Hpo kinase, GST-Mats fusion protein was incubated with cell lysate that contained Flag-tagged Hpo protein. Hpo can be pulled down by GST-Mats but not GST, indicating that Mats was involved in the interaction with Hpo (Figure 3D). In co-immunoprecipitation experiments, Mats was shown to be associated with Hpo kinase when expressed in HEK293T cells, and Mats can also interact with the endogenous human Mst1 (hMst1) protein in living cells (data not shown). Moreover, the fly Hpo protein was found to be able to associate with the endogenous hMats protein in HEK293T cells (data not shown). Similarly, human Mats1 can also be associated with the endogenous hMst1 kinase protein (Figure 3E, lanes 2 and 5; data not shown). As a negative control, GFP was not precipitated under the same conditions (Figure 3E, lanes 3 and 6). Of note, Mats–Hpo/Mst interaction was weaker compared to Mats–Wts protein interaction. Interestingly, hMst1 did not appear to co-exist in the Wts/Mats protein complex in transfected cells (Lai et al, 2005; data not shown). Thus, Mats protein is able to specifically associate with Hpo/Mst, which would allow Hpo/Mst kinases to be more effective in phosphorylating Mats. This mechanism of Mats regulation by Hpo/Mst kinases is conserved from flies to humans. Hpo phosphorylation activates Mats to upregulate Wts protein kinase To reveal the significance of Hpo-mediated phosphorylation of Mats, we have devised a functional assay to measure the ability of Mats to stimulate Wts kinase activity with or without Hpo phosphorylation. To begin with, bacterially produced GST-Mats protein was treated with immobilized Hpo-Flag or HpoKD-Flag, and then collected from supernatant. As shown in a control experiment, the supernatant contained only phosphorylated Mats, no detectable Hpo kinase (Figure 4A, lane 7). Thus, Hpo kinase was unlikely responsible for the subsequent phosphorylation reaction. After Hpo-mediated phosphorylation using cold ATP, Mats protein was incubated with Wts kinase in the presence of radioactive [γ-32P]ATP. Wts kinase activity was measured by the incorporation of 32P into Yki, a substrate of Wts kinase (Huang et al, 2005). Wts activity was hardly detected in the absence of Mats (Figure 4A, lanes 1) or when HpoKD-treated Mats was added (Figure 4A, lane 3). Hpo phosphorylation, however, increased the ability of Mats to stimulate the catalytic activity of Wts kinase (Figure 4A, lane 2). Similar observations were also made with the human Mats1 protein when it was tested in this in vitro kinase assay (data not shown). Moreover, Yki was not phosphorylated when WtsKD was tested in this assay (Figure 4A, lanes 4–6), suggesting that Wts was responsible for Yki phosphorylation. Thus, phosphorylation of Mats by Hpo makes Mats more potent to activate Wts kinase, and this Hpo-mediated activation of Mats is evolutionarily conserved. Figure 4.Hpo phosphorylation of Mats increases the affinity between Mats and Wts and the ability of Mats to activate Wts. (A) Equal amounts of bacterially produced GST-Mats were preincubated for cold phosphorylation with Hpo or HpoKD immobilized on agarose beads, and then collected from supernatant and mixed with Myc-Wts for in vitro kinase reactions using [γ-32P]ATP. Myc-Wts was produced in transfected HEK293T cells, which were not treated with OA. GST-Yki was used as a substrate of Wts kinase. To ensure that immobilized Hpo kinase proteins were not carried over to the subsequent Wts-mediated phosphorylation reaction, [γ-32P]ATP was added in the Hpo-mediated kinase reaction. Whereas phospho-GST-Mats was detected in both supernatant and pellet (lanes 7 and 8), Hpo protein was exclusively found only in the pellet (lane 8). Thus, phosphorylation of Yki (lane 2) must be mediated by Wts kinase. Indeed, Yki phosphorylation was not detectable when WtsKD was used (lane 5). (B) Phosphorylation of Mats by Hpo increases the affinity between Wts and Mats proteins. Equal amounts of Myc-Wts produced in HEK293T cells treated without (lanes 1 and 2) or with (lanes 3 and 4) OA were linked to anti-Myc agarose beads, and GST-Mats treated with Hpo (lanes 1 and 3) or HpoKD (lanes 2 and 4) was tested for their ability to associate with Wts. Download figure Download PowerPoint Hpo phosphorylated Mats displays increased affinity to Wts protein kinase Hpo phosphorylation of Mats makes Mats a more potent activator of Wts kinase, which might be partly caused by an increased affinity between Wts and Hpo phosphorylated Mats. To test this, Mats protein was treated with Hpo kinase or HpoKD in the presence of cold ATP. An equal amount of Wts protein produced in transfected HEK293T cells was used in in vitro protein-binding analysis. The amount of Wts and Mats proteins derived from Wts–Mats complexes was examined by Western blot analysis. As expected, we found that more Hpo-treated Mats proteins were detected in Wts–Mats complexes than in those treated with HpoKD (Figure 4B, compare lane 1 with lane 2, and lane 3 with lane 4). Thus, phosphorylation of Mats by Hpo kinase increases the affinity between Mats and Wts. Moreover, Wts protein derived from okadaic acid (OA)-treated cells exhibited an increased affinity to Mats (Figure 4B, compare lane 3 with lane 1, and lane 4 with lane 2), suggesting that Wts phosphorylation may play a role in increasing its affinity to Mats. Wts protein kinase is activated by Mats in living cells To investigate how Wts kinase is regulated in living cells, Wts protein was expressed in HEK293T cells under various conditions and immunoprecipitated for analysis of its kinase activity to autophosphorylate and phosphorylate Mats. Whereas Wts protein isolated from transfected cells in the absence of OA treatment did not display any detectable kinase activity with or without Mats overexpression (Figure 5A, lanes 1 and 2), treatment of wts-transfected cells with OA markedly increased Wts kinase activity, by 17-fold (Figure 5A, compare lane 3 with lane 1). Coexpression of Wts with Mats in OA-treated cells further increased Wts kinase activity four-fold (Figure 5A, compare lane 4 with lane 3). Clearly, this included the effect of Mats on Wts production and/or stability as Mats increased the steady levels of Wts protein (Figure 5A, the third and fifth panels from the top). After normalizing the amount of Myc-Wts protein used in the kinase reactions, Mats was found to be able to increase Wts kinase activity by two-fold (Figure 5A, compare lane 4 with lane 3, the top and third panels). Similar results were observed using GST-Yki as a substrate (Figure 5C and data not shown). Thus, Mats is a coactivator of Wts kinase for phosphorylation of targets such as Yki. In fly S2 cells, Wts kinase activity was increased by Mats with or without OA treatment (data not shown), suggesting that Wts and Mats are not normally inhibited by protein phosphatases in this cell type. Consistent with this notion, Hpo kinase is active in S2 cells in the absence of OA treatment (Figure 3A and B), to constitutively activate Wts. As OA functions to block protein phosphatases, such as PP2A, our results suggest that Mats and/or Wts phosphorylation are critical for Wts kinase activation in living cells. Figure 5.Mats is a phosphoprotein and Mats is critical for Hpo-mediated Wts activation in living cells. (A) OA treatment as well as coexpression of Mats increased the catalytic activity of Wts kinase as shown in an in vitro kinase assay. Equal amounts of Myc-wts and HA-mats DNA were transfected into HEK293T cells. Myc-Wts was immunoprecipitated from cells that were cotransfected without (lanes 1 and 3) or with (lanes 2 and 4) HA-mats in the absence (lanes 1 and 2) or presence (lanes 3 and 4) of OA treatment as indicated. (B) Both Mats and Wts are phosphoproteins in living cells. Using a TAP method, the HA-Mats protein complex was highly purified and examined by SDS–PAGE analysis. Sypro Ruby staining was used to detect all proteins that include HA-Mats and other proteins in the HA-Mats complex. Pro-Q staining identified phosphoproteins. HEK293T cells were either single or double-transfected with or without OA treatment as indicated. (C) Hpo activates Wts kinase and Mats is critical for Hpo-mediated Wts activation in living cells. HEK293T cells were either double or triple-transfected as indicated. After immunoprecipitating Myc-Wts or Myc-WtsKD protein complex using anti-Myc antibodies, HA-Mats, Myc-Wts/Myc-WtsKD and Hpo-Flag/HpoKD-Flag proteins were examined by Western blot analysis. Equal amounts of Myc-Wts/Myc-WtsKD proteins were used for in vitro kinase reactions, and catalytic activities of Wts and Hpo for autophosphorylation were measured. Moreover, bacterially produced GST-Yki protein was added to determine Wts kinase activity. Hpo does not appear to phosphorylate Yki (lane 4 and data not shown). The cells were not treated with OA. Download figure Download PowerPoint Mats and Wts are phosphoproteins in living cells To determine the effect of OA treatment on Wts and Mats phosphorylation, Mats was tagged and the Mats protein complex was isolated by a tandem affinity purification (TAP) method. Phosphorylation state of Mats and Wts
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