Identification of Reelin-induced Sites of Tyrosyl Phosphorylation on Disabled 1*

Lakhu KeshvaraDagger , David Benhayon§, Susan MagdalenoDagger , and Tom CurranDagger

From the Dagger  Department of Developmental Neurobiology, St. Jude Children's Research Hospital, Memphis, Tennessee 38105 and the § Department of Anatomy and Neurobiology, University of Tennessee, Memphis, Tennessee 38163

Received for publication, February 14, 2001


    ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

The study of mice with spontaneous and targeted mutations has uncovered a signaling pathway that controls neuronal positioning during mammalian brain development. Mice with disruptions in reelin, dab1, or both vldlr and apoER2 are ataxic, and they exhibit severe lamination defects within several brain structures. Reelin is a secreted extracellular protein that binds to the very low density lipoprotein receptor and the apolipoprotein E receptor 2 on the surface of neurons. Disabled-1 (Dab1), an intracellular adapter protein containing a PTB (phosphotyrosine binding) domain, is tyrosyl-phosphorylated during embryogenesis, but it accumulates in a hypophosphorylated form in mice lacking Reelin or both very low density lipoprotein receptor and apolipoprotein E receptor 2. Dab1 is rapidly phosphorylated when neurons isolated from embryonic brains are stimulated with Reelin, and several tyrosines have been implicated in this response. Mice with phenylalanine substitutions of all five tyrosines (Tyr185, Tyr198, Tyr200, Tyr220, and Tyr232) exhibit a reeler phenotype, implying that tyrosine phosphorylation is critical for Dab1 function. Here we report that, although Src can phosphorylate all five tyrosines in vitro, Tyr198 and Tyr220 represent the major sites of Reelin-induced Dab1 phosphorylation in embryonic neurons.


    INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

The formation of the mammalian central nervous system involves a complex pattern of neuronal migration that results in the organization of several neuronal populations into precise layers (1, 2). Over the past five years, a great deal has been learned about the molecular mechanisms that control cell migration in the developing brain from the study of mutant mice. In particular, the identification of reelin, the gene mutated in the classic ataxic mutant mouse reeler, has uncovered a signaling pathway that is critical for cell positioning (3). Detailed histological studies of reeler mice revealed severe lamination defects in the cerebral cortex, cerebellum, hippocampus, and other laminated structures in the central nervous system (4). Remarkably, mutations in Disabled 1 (Dab1),1 an intracellular adapter protein (5-8), or both the very low density lipoprotein receptor and apolipoprotein E receptor 2 (9) result in identical defects in mice. The reelin gene encodes a large protein secreted by several populations of neurons in the developing brain, including Cajal-Retzius cells in the neocortex and granule cell precursors in the cerebellum (3, 10). Biochemical studies have demonstrated that Reelin serves as a ligand for lipoprotein receptors (11, 12). Taken together, these findings suggest a model in which Reelin binds to lipoprotein receptors present on target neurons that express Dab1, initiating an intracellular signaling cascade. Recently, reelin has been shown to be mutated in a rare form of autosomal lissencephaly in humans (13), and alterations in the Reelin pathway have also been proposed to be associated with other neurological disorders (14, 15).

Although the exact mechanism involved in Reelin signaling is unclear, it has been proposed that Dab1 acts as an intracellular adapter molecule downstream of Reelin. Dab1 was first identified as a Src-binding protein in a yeast two-hybrid screen (16). The amino terminus of Dab1 contains a PTB (phosphotyrosine binding) domain that is structurally similar to the PTB domains of Shc and Numb (17). Although PTB domains were originally identified as protein interaction domains that recognized tyrosyl-phosphorylated Asn-Pro-X-Tyr (NPXY) motifs present on target proteins, they have recently emerged as a more diverse family of protein modules that vary in their recognition sequences (17). The Dab1 PTB domain interacts with NPXY sequences within the cytoplasmic regions of several membrane-bound proteins, including lipoprotein receptors (18) and amyloid precursor protein family proteins (19, 20). The Dab1 PTB domain has a preference for the unphosphorylated NPXY motif, and phosphorylation of the tyrosine residue is inhibitory to the interaction of Dab1 PTB domain with amyloid precursor protein (20). The NPXY motif serves as an internalization signal for the low density lipoprotein receptor (21), and the interaction with Dab1 has been suggested to regulate the rate of receptor internalization (22).

Dab1 accumulates in mice lacking Reelin or both very low density lipoprotein receptor and apolipoprotein E receptor 2 (6), suggesting that Dab1 is degraded as a consequence of Reelin signaling. In wild-type mice, Dab1 is phosphorylated on tyrosines during embryogenesis (16). In contrast, tyrosyl phosphorylation of Dab1 is greatly diminished in reeler mice, despite the elevated levels of the protein. However, stimulation of forebrain neurons from reeler embryos with exogenous Reelin can result in a rapid and dramatic induction of Dab1 tyrosyl phosphorylation (23). This has led to the hypothesis that tyrosyl phosphorylation of Dab1 is a critical step in the Reelin-signaling pathway. Indeed, mice expressing a mutant form of Dab1, in which a cluster of five tyrosine residues located immediately downstream of the PTB domain were replaced with phenylalanine, exhibit a reeler phenotype (24). Although this study supported a role for Dab1 phosphorylation in neuronal positioning, it did not identify the specific sites involved. Here, we identify the sites of Reelin-induced tyrosyl phosphorylation on Dab1 in neurons. This is a critical first step in understanding the mechanisms that couple the molecular events triggered by Reelin to the cellular processes that mediate neuronal positioning in the developing brain.

    EXPERIMENTAL PROCEDURES
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Construction of Expression Plasmids-- The GST-Dab1 fusion construct and Dab1-hemagglutinin expression plasmid have been described previously (19). GST fusions of the Dab1 PTB domain (GST-Dab11-179), middle region (GST-Dab1180-399), and the carboxyl-terminal region (GST-Dab1400-555) were prepared by subcloning the corresponding polymerase chain reaction products into pGEX4T3 (Amersham Pharmacia Biotech). Site-directed mutagenesis was conducted using the QuikChange site-directed mutagenesis kit (Stratagene). The mutagenesis reactions were performed in the pGEX4T3 and pcDNA3 vectors containing a full-length Dab1 clone according to the manufacturer's protocol and confirmed by DNA sequencing.

Expression of GST Fusion Proteins-- Fusion proteins were expressed in BL21 bacterial strains as described previously (19). Isopropyl-1-thio-beta -D-galactopyranoside-induced bacterial pellets were lysed by sonicating in phosphate-buffered saline/Tween containing 5 mM EDTA, 2 mM phenylmethylsulfonyl fluoride, 40 µg/ml aprotinin, and 40 µg/ml leupeptin. The lysates were incubated with glutathione-Sepharose (Amersham Pharmacia Biotech) at 4 °C. Bound proteins were then used as substrates in Src kinase reactions in vitro.

Kinase Reactions-- GST fusion proteins (~5 µg each) immobilized on glutathione-Sepharose were phosphorylated by ~15 units of purified active c-Src (Upstate Biotechnology) in 50 µl of kinase reaction buffer (25 mM Tris-HCl, pH 7.3, 25 mM MgCl2, 10 mM MnCl2, 0.5 mM EGTA, 0.05 mM sodium orthovanadate, 0.5 mM dithiothreitol, 100 µM ATP, and 25 µCi of [gamma -32P]ATP). The kinase reactions were carried out at 30 °C for 30 min. The reactions were stopped by the addition of SDS sample loading buffer, and protein samples were boiled for 5 min. Phosphoproteins were separated by SDS-PAGE, transferred to nitrocellulose membranes, and visualized by autoradiography.

Phosphopeptide Mapping-- Phosphoproteins were excised from nitrocellulose membranes and digested with trypsin essentially as described (25). Briefly, membrane pieces were first incubated in 0.5% polyvinylpyrrolidone (PVP-360; Sigma), 100 mM acetic acid for 30 min at 37 °C. After extensive washing with H2O, membranes were incubated for 2 h at 37 °C with 10 µg of L-1-tosylamido-2-phenylethyl chloromethyl ketone-treated trypsin (Sigma) in 50 mM NH4HCO3. This was followed by an overnight digestion with an additional 10 µg of trypsin. Samples were lyophilized and dissolved in alkaline PAGE sample buffer (125 mM Tris-HCl, pH 6.8, 6 M urea, and bromphenol blue). The tryptic phosphopeptides were resolved by electrophoresis on an alkaline 40% polyacrylamide gel, as described (26). The samples were electrophoresed overnight at 7 mA until the tracking dye had migrated to RF = 0.5. The gel was dried, and phosphopeptides were detected by autoradiography.

Cell Culture and Immunoprecipitations-- HEK-293T cells (ATCC) were transfected with pcDNA3.1-Dab1-hemagglutinin or mutant forms of Dab1 and a constitutively active form of Src (pcDNA-Src527F) using FuGene 6 transfection reagent (Roche Molecular Biochemicals). 24 h after transfection, cells were lysed in cell lysis buffer (25 mM Tris-HCl, 1% Nonidet P-40, 150 mM NaCl, 5 mM EDTA, 1 mM sodium orthovanadate, 5 mM NaF, 10 µg/ml each aprotinin and leupeptin). The lysates were cleared by centrifugation and incubated with anti-hemagglutinin antibodies (Covance). Immunoprecipitates were resolved by SDS-PAGE and transferred to nitrocellulose for analysis by Western blotting.

Reelin Purification-- Expression of Reelin in 293T cells has been described previously (11). Briefly, Nephrigen (Celox Laboratories Inc.) supernatant containing Reelin was clarified by centrifugation for10 min at 5000 × g at 4 °C. A saturated ammonium sulfate (4.1 M) solution was added to the Nephrigen supernatant to bring it from 0 to 45% saturation. Ammonium sulfate was gradually added to a slowly stirring solution over a period of 30 min at 4 °C, and the solution was stirred for an additional 30 min to allow proteins to precipitate completely. The precipitate was collected by centrifugation for 30 min at 12,000 × g at 4 °C. After air-drying, the pellet was redissolved in 10 mM HEPES (pH 7.5) containing 10% glycerol and stored at -80 °C. To estimate the concentration of Reelin, samples were separated on SDS-PAGE gels and compared with known quantities of bovine serum albumin by staining with Coomassie Brilliant Blue. This technique yielded a 50-fold purification, and partially purified full-length Reelin represented ~6% of the total precipitated proteins.

Primary Culture and Reelin Treatment-- Treatment of neurons with Reelin-enriched supernatants has been described previously (11). Briefly, brains of E16 reeler embryos were removed, and neurons were isolated by trituration in Hanks' buffered salt solution. Neurons were separated into aliquots in several microcentrifuge tubes and then resuspended in either Dulbecco's modified Eagle's medium (DMEM) or DMEM containing 1 ng/µl Reelin. After incubation at 37 °C for 15 min, neurons were collected by centrifugation and either frozen at -80 °C or lysed immediately in cell lysis buffer. The lysates were pre-cleared by centrifugation at 14,000 rpm for 15 min, and the supernatant was used for anti-Dab1 (goat anti-Dab1 PTB, ExAlpha Biologics) immunoprecipitations.

Phosphopeptide Antibodies and Immunoblotting-- Synthesis of peptides and generation of phosphopeptide antibodies were carried out by Alpha Diagnostic International (San Antonio, TX). Rabbits were immunized with KLH-coupled phosphopeptides PY185, CEQAVY(PO4)QTILEED; PY198/200, CEDPVY(PO4)QY(PO4)IVFEAG; PY220, CETEENIVY(PO4)QVPTSQK; and PY232, CKKEGVY(PO4)DVPKSQP. Phosphopeptide PY185 and an unphosphorylated form of this peptide were conjugated to bovine serum albumin (BSA) using Imject maleimide-activated BSA (Pierce). Unphosphorylated GST-Dab1, Src-phosphorylated GST-Dab1, and GST-Dab1 mutant proteins were used in immunoblotting assays to characterize the antisera.

    RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Dab1 Is Phosphorylated by Src in the Middle Region-- Previous studies demonstrated that Dab1 binds to members of the Src family of kinases and that Dab1 can be phosphorylated by Src in transfected cells (16, 24). To determine if Src phosphorylates Dab1 directly, we used purified active Src (Src527F) to phosphorylate GST fusion proteins containing Dab1. Indeed, as shown in Fig. 1A, Src efficiently phosphorylated GST-Dab1, whereas GST alone was not phosphorylated. As a first step toward identifying the in vitro sites of phosphorylation, we used GST fusion proteins containing three distinct Dab1 regions as substrates. As illustrated in Fig. 1B, these domains comprised the PTB domain (GST-Dab11-179), the middle region (GST-Dab1180-399), and the carboxyl terminus (GST-Dab1400-555) of Dab1. Interestingly, only the middle region of Dab1 was phosphorylated by Src (Fig. 1A). This region contains six tyrosines, five of which were previously suggested as sites of Dab1 phosphorylation in transient transfection assays.


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Fig. 1.   Region of Src phosphorylation on Dab1. A, GST alone or GST fusion proteins containing either full-length Dab1, PTB domain (GST-Dab11-179), Mid region (GST-Dab1180-399), or carboxyl-terminal region (CT; GST-Dab1400-555) were phosphorylated with Src in the presence of [gamma -32P]ATP. The proteins were resolved by SDS-PAGE, transferred to nitrocellulose, and detected by autoradiography. B, a schematic showing the region of phosphorylation in relation to the remaining molecule. A partial amino acid sequence of this region containing the cluster of tyrosines is shown. All six tyrosine residues (Tyr185, Tyr198, Tyr200, Tyr220, Tyr232, and Tyr300) present within the middle region are indicated.

Mapping of the in Vitro Phosphorylation Sites-- A combination of peptide mapping and mutagenesis approaches was used to identify the specific sites of phosphorylation by Src in vitro. Phosphopeptides generated by tryptic digestion of in vitro phosphorylated Dab1 were readily separated by one-dimensional 40% alkaline-PAGE. As shown in Fig. 2A, complete digestion of phosphorylated wild-type GST-Dab1 consistently yielded four phosphopeptides. These phosphopeptides were designated numbers 1-4 starting from the most slowly migrating peptide. Occasionally, an additional phosphopeptide (indicated by an asterisk, Fig. 2A) was also observed to migrate slightly faster than phosphopeptide 3. Tyrosine 300 is not present in any of these phosphopeptides as it lies in a 16-kDa fragment of Dab1 that is never found to be phosphorylated in vitro.


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Fig. 2.   One-dimensional tryptic phosphopeptide map of Dab1 phosphorylated by Src. A, GST fusion proteins of either wild-type (Wt) Dab1 or Dab1 mutants containing phenylalanine substitutions in place of tyrosines 185 (185F), 198 (198F), 220 (220F), 232 (232F), or both 198 and 200 (198F/200F) were phosphorylated using Src. The phosphorylated proteins were separated by SDS-PAGE, transferred to nitrocellulose, and located by autoradiography. The proteins were trypsinized off the membrane, and the tryptic fragments were resolved by alkaline 40% polyacrylamide gel electrophoresis. The phosphopeptides were visualized by autoradiography. B, a schematic showing the identity of the tryptic phosphopeptides, including the sites of phosphorylation within each peptide.

To identify the specific sites of phosphorylation within Dab1, we generated GST-Dab1 fusion proteins containing single phenylalanine substitutions at tyrosines 185 (185F), 198 (198F), 200 (200F), 220 (220F), and 232 (232F) and a GST-Dab1 fusion with double substitutions at residues 198 and 200 (198F/200F). The mutant GST-Dab1 fusion proteins were phosphorylated by Src in vitro, tryptic phosphopeptide maps were generated, and the results are shown in Fig. 2. Phenylalanine substitution at residues 220 and 232 resulted in the loss of phosphopeptides 2 and 4, respectively. Therefore, Src phosphorylated Tyr220 and Tyr232 of Dab1 in vitro. However, given the low intensity of the band corresponding to peptide 4, Tyr232 was considered to be a minor site of in vitro phosphorylation. The remaining three potential sites of phosphorylation, Tyr185, Tyr198, and Tyr200, are located within a single tryptic peptide fragment, which complicates analysis. Single substitution of either Tyr185 or Tyr200 did not result in the loss of any of the four major peptides, indicating that these two tyrosines were not major phosphorylation sites. In contrast, substitution of Tyr198 with phenylalanine resulted in a dramatic loss of phosphopeptide 1 and phosphopeptide 3 and the appearance of a novel minor peptide (indicated by an arrow, Fig. 2A). Therefore, phosphopeptide 1 probably represented a tryptic fragment that was almost exclusively phosphorylated on Tyr198, whereas phosphopeptide 3 likely represented a doubly phosphorylated form of the same tryptic fragment containing Tyr198(P) and either Tyr185(P) or Tyr200(P). The novel minor phosphopeptide in tryptic digest of GST-Dab1198F probably appeared as a result of a single phosphate present on the same peptide at either Tyr185 or Tyr200. Interestingly, tryptic digest of wild-type GST-Dab1 contained an additional phosphopeptide (indicated by an asterisk, Fig. 2A) with a slightly faster migration rate than phosphopeptide 3. It is possible that this band represented a variant form of phosphopeptide 3 with a migration rate that would depend on which of the other tyrosine residues was phosphorylated within the single tryptic fragment. The exact identity of this phosphopeptide was difficult to establish, because this band was absent in digests of all mutant forms of GST-Dab1 fusion proteins. Consistent with the possibility that phosphopeptide 3 resulted from phosphorylation of Tyr198 and phosphorylation of either Tyr185 or Tyr200, both phosphopeptides 1 and 3 were absent from tryptic digests of the GST-Dab1 fusion protein containing phenylalanine substitutions at both residues 198 and 200. However, since phosphopeptide 3 persisted in the absence of Tyr200, it is likely that Tyr185 was also phosphorylated by Src in vitro. Therefore, the most straightforward interpretation of our results is that phosphopeptide 3 resulted from phosphorylation of Tyr198 and either Tyr185 or Tyr200. Although it was difficult to establish the relative contributions of Tyr185(P) and Tyr200(P) toward the composition of phosphopeptide 3, our results suggest that Tyr198 and Tyr220 were major in vitro phosphorylation sites, and Tyr185, Tyr200, and Tyr232 were minor Src phosphorylation sites.

Characterization of Phosphopeptide-specific Dab1 Antibodies-- A combination of metabolic radiolabeling of cells with orthophosphate and tryptic phosphopeptide mapping has been the traditional approach to identify in vivo sites of protein phosphorylation. Due to inefficient radiolabeling of Dab1 in neurons and the presence of multiple tyrosines (Tyr185, Tyr198, and Tyr200) within a single tryptic fragment, it was difficult to employ this technique to identify the in vivo sites of Dab1 phosphorylation. Therefore, we chose to prepare phosphopeptide-specific antibodies to confirm the in vitro phosphorylation sites and to investigate in vivo phosphorylation of Dab1. Peptides containing single phosphotyrosines Tyr185(P) (PY185), Tyr220(P) (PY220), and Tyr232(P) (PY232) were used to immunize rabbits. Given the close proximity of Tyr198 and Tyr200, we used a synthetic peptide containing both tyrosines in the phosphorylated form (PY198/200) for immunization. The efficacy of the each antibody was determined by Western blot assays in which the antisera were tested against unphosphorylated GST-Dab1 and GST-Dab1 phosphorylated with Src in vitro. As shown in Fig. 3A, the antisera raised against PY198/200, PY220, and PY232 recognized only phosphorylated GST-Dab1, with no significant cross-reactivity with unphosphorylated GST-Dab1. Western blotting using anti-Dab1 antibodies confirmed that equivalent levels of unphosphorylated and phosphorylated Dab1 were present. Antisera from three different rabbits immunized with the PY185 peptide failed to show any specific reactivity toward phosphorylated GST-Dab1. This lack of reactivity was not due to a low titer, because the antisera strongly recognized bovine serum albumin-conjugated PY185 phosphopeptide in a Western blot assay without any cross-reactivity toward an unphosphorylated form of the peptide. Therefore, since the antisera recognized a synthetic phosphopeptide but did not recognize Src-phosphorylated GST-Dab1, it can reasonably be concluded that Tyr185 was not phosphorylated by Src in vitro. This finding was consistent with our phosphopeptide mapping results, which indicated that Tyr185 was a minor site of in vitro phosphorylation.


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Fig. 3.   Characterization of the phosphopeptide-specific antibodies. A, GST-Dab1 was either left untreated (U) or phosphorylated (P) by Src. The proteins were separated by SDS-PAGE and transferred to nitrocellulose. The membranes were subjected to Western blotting using anti-PY185, anti-PY198/200, anti-PY220, or anti-PY232 antibodies. The membranes were stripped and reprobed with anti-Dab1 antibodies to show equal loading of the proteins. The anti-PY185 antibody was also tested in a Western blot using bovine serum albumin conjugates of the unphosphorylated (Y185) and the phosphorylated (PY185) peptides corresponding to this phosphorylation site (right panel). B, GST fusions of Dab1 containing phenylalanine substitutions at residues 198 (198F), 200 (200F), 198 and 200 (198F/200F), 220 (220F), or 232 (232F) were either phosphorylated by Src (P) or left untreated (U). Immunoblotting was then carried out using either anti-PY198/200 (upper panel), anti-PY220 (middle panel), or anti-PY232 (lower panel) antibodies. The membranes were then stripped and reprobed with anti-Dab1 antibodies to confirm equal protein loading. Wt, wild type.

Although the data in Fig. 3A show that the phosphopeptide-specific antibodies specifically recognized phosphorylated Dab1, the utility of these antibodies requires that they also exhibit sequence specificity. To determine sequence specificity, the antibodies were tested in Western blots against unphosphorylated and Src-phosphorylated wild-type GST-Dab1 or GST-Dab1 fusion proteins containing single phenylalanine substitutions at Tyr198, Tyr200, Tyr220, and Tyr232 or double mutations of Tyr198 and Tyr200. As shown in Fig. 3B, the antibodies raised against PY198/200, PY220, and PY232 exhibited strong sequence specificity. The anti-PY220 and anti-PY232 antibodies did not recognize phosphorylated GST-Dab1 containing single phenylalanine substitutions in place of the corresponding tyrosines. The specificity of anti-PY198/200 was determined by testing it on GST-Dab1 fusion proteins that contained either single phenylalanine substitutions in place of Tyr198 and Tyr200 or double substitution of both Tyr198 and Tyr200. The antibodies did not recognize Src-phosphorylated GST-Dab1 when Tyr198 alone or both Tyr198 and Tyr200 were substituted with phenylalanine. In contrast, the antisera contained partial reactivity toward Dab1 containing a single mutation of Tyr200, indicating that Tyr198(P) is the major epitope for this antibody but both Tyr198(P) and Tyr200(P) are required for optimal recognition of phosphorylated Dab1.

Phosphorylation of Dab1 in Transfected 293T Cells-- Dab1 is efficiently phosphorylated by Src in transfected cells. Mapping studies using mass spectrometry to identify tryptic phosphopeptides showed that Tyr198 and Tyr232 were phosphorylated by Src (24). However, tyrosyl phosphorylation of Dab1 remained undiminished when these two residues were mutated to phenylalanine, suggesting that Dab1 was phosphorylated on other tyrosine residues as well. Phenylalanine substitution of all five tyrosines (Tyr185, Tyr198, Tyr200, Tyr220, and Tyr232) present immediately downstream of the PTB domain abrogates Src phosphorylation in transfected cells (24). To identify specific sites of tyrosyl phosphorylation, we transfected 293T cells with Src and with either wild-type Dab1 or Dab1 carrying single phenylalanine substitutions at Tyr198, Tyr200, Tyr220, Tyr232 or a double substitution of Tyr198 and Tyr200. Western blots using the phosphopeptide-specific antibodies were then carried out to determine the phosphorylation status of each of the mapped tyrosine residues. As shown in Fig. 4A, Tyr220 and Tyr232 were clearly phosphorylated by Src. The antibody raised against the doubly phosphorylated PY198/200 peptide did not recognize Dab1 if Tyr198 alone or both Tyr198 and Tyr200 were mutated to phenylalanine. In contrast, mutation of Tyr200 did not have any effect on the ability of this antibody to recognize phosphorylated Dab1, implying that Tyr200 was not phosphorylated. To determine if Tyr185 was phosphorylated by Src, Dab1 was expressed either with Src or without Src in 293T cells, and anti-Dab1 immunoprecipitates were immunoblotted with anti-PY185. As shown in Fig. 4B, Tyr185 was not phosphorylated, even though Dab1 was tyrosyl-phosphorylated in the presence of Src. Therefore, these results show that Dab1 is phosphorylated by Src on Tyr198, Tyr220, and Tyr232 in 293T cells.


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Fig. 4.   Dab1 tyrosyl phosphorylation sites in 293T cells. A, wild-type (Wt) Dab1 or mutant forms of Dab1 carrying phenylalanine substitutions at residues 198 (198F), 200 (200F), 220 (220F), 232 (232F), or both 198 and 200 (198F/200F) were expressed 293T cells along with active form of Src. Dab1 immunoprecipitates were immunoblotted with various phosphopeptide antibodies and anti-Dab1 antibody. B, Dab1 expressed in 293T cells alone (-) or with Src (+) was immunoprecipitated (IP) and probed with either anti-PY185 or anti-phosphotyrosine (Anti-PTyr) antibodies.

Identification of Sites of Reelin-induced Phosphorylation-- Dab1 is tyrosyl-phosphorylated in a Reelin-dependent manner, and Reelin-induced phosphorylation of Dab1 in embryonic neurons is an important biochemical assay for Reelin function. As shown in Fig. 5A, tyrosyl phosphorylation of Dab1 increased dramatically when neurons from reeler embryos were treated with Reelin. We used the phosphopeptide antibodies to identify the sites of Reelin-induced tyrosyl phosphorylation on Dab1 to detect Dab1 in cultured neurons. Neurons isolated from embryonic brains of reeler mice were either left untreated or treated with Reelin. Anti-PY185, anti-PY198/200, anti-PY220, and anti-PY232 were used in Western blots to detect phosphorylated Dab1 in the anti-Dab1 immunoprecipitates. As shown in Fig. 5, only the anti-PY198/200 and anti-PY220 recognized Dab1 in Reelin-treated neurons, indicating that Tyr220 and either Tyr198 alone or both Tyr198 and Tyr200 were phosphorylated in neurons stimulated with Reelin. In three independent experiments, anti-PY185 and anti-PY232 did not react against Dab1 from Reelin-treated neurons, suggesting that these two tyrosines were not phosphorylated to any significant extent in response to Reelin treatment. Tyrosyl phosphorylation of Dab1 was very faint in the absence of Reelin, and only the anti-PY220 antisera reacted against Dab1 from unstimulated neurons. Therefore, although it is possible that Dab1 is basally phosphorylated on other tyrosines, our results suggest that Tyr220 is the major site of phosphorylation in absence of Reelin.


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Fig. 5.   Reelin-induced sites of Dab1 phosphorylation. A, neurons from E16 reeler embryonic brains were incubated with either Dulbecco's modified Eagle's medium (DMEM) alone or Reelin-enriched DMEM. The neurons were then lysed and immunoprecipitated with anti-Dab1 antibodies. The immunoprecipitates were separated by SDS-PAGE, and immunoblots were carried out using anti-phosphotyrosine (anti-PTYR), anti-PY185, anti-PY198/200, anti-PY220, anti-PY232, or anti-Dab1 antibodies. B, a schematic indicating the positions of the tyrosines phosphorylated on Dab1 in neurons treated with Reelin.


    DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Dab1 plays a critical role in controlling neuronal positioning in the developing brain. It functions as an intracellular adapter protein in the Reelin-signaling pathway, although the mechanism by which it mediates downstream signaling is unknown. The most important clue to Dab1 function is that it accumulates in a hypophosphorylated form in reeler mice, and binding of Reelin to lipoprotein receptors triggers tyrosyl phosphorylation of Dab1 in neurons (11, 12). The phosphorylation sites were suspected to be contained within a cluster of five tyrosines located immediately downstream of the Dab1 PTB domain. Indeed, Howell et al. (24) show that a mutant mouse expressing Dab1 with phenylalanine substitutions in place of these five tyrosines exhibited the same phenotype as reeler mice. This provided genetic evidence to support the critical role of Dab1 tyrosyl phosphorylation in the Reelin-signaling pathway. The biochemical consequences of Dab1 tyrosyl phosphorylation are not known, but it is possible that the phosphorylated tyrosines serve to recruit signaling molecules that bind to phosphorylated Dab1 via their SH2 domains. Alternatively, tyrosyl phosphorylation could affect the stability of Dab1 or its interaction with lipoprotein receptors. Therefore, identification of the Reelin-induced phosphorylation sites on Dab1 is critical to identifying downstream signaling components of this pathway.

Dab1 was originally identified in a yeast two-hybrid screen as a Src-binding protein, and it was subsequently shown to be phosphorylated in an Src-dependent manner in cell lines (16). Given the likely role of Src in Dab1 phosphorylation, we used recombinant active Src to map the in vitro sites of Dab1 tyrosine phosphorylation. Using GST fusions of three distinct Dab1 domains as substrates for Src in vitro, we determined that Src phosphorylates several tyrosines that are clustered in the middle region of Dab1 immediately downstream of the PTB domain. Using a combination of site-directed mutagenesis and tryptic phosphopeptide mapping, we showed that the major sites of Src-catalyzed in vitro phosphorylation are Tyr198 and Tyr220, and the minor sites of phosphorylation are Tyr185, Tyr200, and Tyr232. Using antibodies raised against phosphopeptides corresponding to these sites of phosphorylation, we confirmed that Tyr198, Tyr200, Tyr220, and Tyr232 are in vitro Src phosphorylation sites. In transfected 293T cells, Src phosphorylated Dab1 on Tyr198, Tyr220, and Tyr232. Recently, a mass spectrometric approach was used to identify Tyr198 and Tyr232 as sites of Src-catalyzed phosphorylation on Dab1 in transiently transfected 293T cells (24). However, since Dab1 mutants with single phenylalanine substitutions of these two residues did not significantly reduce Dab1 tyrosyl phosphorylation, it was concluded that additional sites must be phosphorylated that are not detected by mass spectrometry. Our finding that Tyr220 is also phosphorylated is consistent with this conclusion. Since the antibodies raised against a synthetic peptide corresponding to the Tyr185(P) phosphorylation site failed to react with phosphorylated Dab1, Tyr185 is unlikely to be a major phosphorylation site.

To identify the sites phosphorylated in response to Reelin, we treated reeler embryonic neurons with Reelin and used phosphopeptide antibodies raised against these putative sites in Western blots. The results of these experiments clearly indicate that Tyr198 and Tyr220 are phosphorylated in response to Reelin treatment. We were unable to determine whether Dab1 is phosphorylated on tyrosine 198 alone or both tyrosines 198 and 200, because the antibody against the doubly phosphorylated PY198/200 phosphopeptide retains reactivity in the absence of Tyr200(P). However, Tyr200 was not a major Src phosphorylation site in vitro or in transfected cells. Therefore, it is unlikely that this tyrosine is a major site of Reelin-induced phosphorylation. Antibodies against PY185 and PY232 did not recognize Dab1 in either Reelin-treated or untreated cells, suggesting that these tyrosines are not phosphorylated to any significant extent in response to Reelin stimulation. Despite the elevated levels of Dab1, tyrosyl phosphorylation of Dab1 is significantly diminished in reeler mice. This makes it very difficult to identify tyrosines that are phosphorylated in the absence of Reelin. However, we were able to detect a very low level of phosphorylation of Tyr220 in untreated neurons. Therefore, our results suggest that a population of Dab1 may be constitutively phosphorylated on this tyrosine in the absence of Reelin.

The finding that Reelin triggers phosphorylation of Tyr198 and Tyr220 has important implications. Although the immediate biochemical consequences of Reelin-induced Dab1 tyrosyl phosphorylation are unknown, tyrosyl-phosphorylated Dab1 is likely to be involved in protein-protein interactions. Dab1 has been shown to interact with SH2 domains of various signaling proteins in vitro (16, 24), but the in vivo interaction of Dab1 with any of these proteins has not been demonstrated. Our results suggest that physiologically relevant interactions of Dab1 with SH2-containing proteins would be mediated by Tyr198(P) and Tyr220(P). The amino acid sequence surrounding Tyr198 is very similar to the juxtamembrane region of platelet-derived growth factor beta -receptor that binds to the SH2 domains of Src family kinases (27). It is conceivable that phosphorylation of this tyrosine would serve to recruit Src family kinases. These kinases may then phosphorylate other proteins that may be associated with Dab1. Alternatively, such kinases may also play a role in amplifying the Reelin signal by increasing Dab1 phosphorylation in a positive feedback loop. The amino acid sequence downstream of Tyr220 represents a minimal consensus sequence, YXXP, for interaction with SH2 domains of various signaling proteins, such as Abl, phospholipase Cgamma , Crk, and Nck (28). Thus, Reelin-induced phosphorylation of Tyr198 and Tyr220 could result in formation of a Dab1-associated signaling complex that would mediate the downstream effects of Reelin.

The kinases responsible for in vivo tyrosyl phosphorylation of Dab1 are not known. It is interesting that the Src-catalyzed in vitro phosphorylation sites are also phosphorylated in neurons stimulated with Reelin. The amino acid sequences upstream of the two major sites of phosphorylation, Tyr198 and Tyr220, share a marked sequence similarity. A hydrophobic residue at the -1 position and acidic residues at positions -3, -4, -6, and -8 relative to the tyrosines are characteristic of phosphorylation sites on substrates of the Src family of kinases (29). Indeed, we have been able to phosphorylate Dab1 in vitro using various tyrosine kinases, including Src and Fyn, and to a lesser extent, Abl. Several Src family tyrosine kinases are widely expressed in the brain during embryogenesis (30). Although Fyn has been suggested to play a role in synaptic plasticity (31), no overt brain phenotype has been associated with src or fyn mutations. Furthermore, tyrosyl phosphorylation of Dab1 is undiminished in mice lacking several Src family kinases (16). However, functional redundancy within this family of kinases has made it very difficult to elucidate the roles of individual kinases by genetic approaches, and it is possible that Dab1 is phosphorylated by more than one Src family kinase. Abl, a close relative of the Src family, has also been implicated in the Reelin-Dab1 pathway. In Drosophila, Dab and Abl are involved in a common pathway that controls the development of axonal tracts (32). Although mice deficient in Abl or Arg, an Abl family member, do not exhibit any phenotypic similarity to reeler mice, mice deficient in both kinases suffer from serious neural tube defects, and embryos fail to survive past embryonic day 9 (33). Therefore, it is possible that Abl or Arg are required for phosphorylation of Dab1, but functional redundancy within this family presents some difficulties in determining their role in Dab1 phosphorylation. We cannot preclude the possibility that more than one tyrosine kinase is involved in complete activation of the Reelin-Dab1 pathway. For example, one kinase may be responsible for the constitutive phosphorylation of Dab1, whereas another kinase may increase Dab1 tyrosyl phosphorylation in response to Reelin.

Identification of the sites of Reelin-induced Dab1 tyrosyl phosphorylation is an important step toward understanding the biochemical function of Dab1 in the Reelin-signaling pathway. Synthetic peptides containing Tyr198 and Tyr220 can be used in biochemical assays to identify and purify tyrosine kinases involved in Dab1 phosphorylation. Furthermore, the availability of antibodies specific for these phosphorylation sites makes it possible to identify other upstream signaling pathways that may cross-talk with the Reelin pathway. Tyrosine phosphorylation of Dab1 is an obligatory step in Reelin-Dab1 signaling, and Reelin-induced phosphorylation served as an important assay for identifying lipoprotein receptors as key components of the Reelin-signaling pathway. The availability of phosphorylation site-specific antibodies may not only allow us to identify additional components of this pathway, but they may also help identify other signaling pathways that cross-talk with the Reelin-Dab1 pathway.

    ACKNOWLEDGEMENTS

We thank Sara Courtneidge for providing the Src527F expression plasmid and members of the Curran lab for helpful comments on the manuscript.

    FOOTNOTES

* This work was supported in part by National Institutes of Health (NIH) Cancer Center Support CORE Grant P30 CA21765, NIH Grant RO1-NS36558 (NINDS) (to T. C.), the American Lebanese Syrian Associated Charities (ALSAC), and the Human Frontiers Science Program RG67/98.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

To whom correspondence should be addressed. Tel.: 901-495-2253; Fax: 901-495-2270; E-mail: fos1@aol.com.

Published, JBC Papers in Press, February 23, 2001, DOI 10.1074/jbc.M101422200

    ABBREVIATIONS

The abbreviations used are: Dab1, Disabled-1; GST, glutathione S-transferase; , PAGE, polyacrylamide gel electrophoresis; PTB, phosphotyrosine binding; SH2, Src homology 2.

    REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

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