Interaction of Two Actin-binding Proteins, Synaptopodin and alpha -Actinin-4, with the Tight Junction Protein MAGI-1

doi:10.1074/jbc.M203072200

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Interaction of Two Actin-binding Proteins, Synaptopodin and $alpha$ -Actinin-4, with the Tight Junction Protein MAGI-1^*

Kevin M. Patrie^§, Andrew J. Drescher, Ajith Welihinda^¶, Peter Mundel^**, and Ben Margolis^§§^¶¶

From the Departments of Internal Medicine and Biological Chemistry and the ^§§ Howard Hughes Medical Institute, University of Michigan, Ann Arbor, Michigan, 48109-0650 and the Departments of Medicine and of Anatomy and Structural Biology, Albert Einstein College of Medicine, Bronx, New York 10461

Received for publication, March 29, 2002, and in revised form, May 28, 2002

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In an attempt to find podocyte-expressed proteins that may interact with the tight junction protein MAGI-1, we screened aglomerulus-enriched cDNA library with a probe consisting of bothWW domains of MAGI-1. One of the isolated clones contained twoWW domain-binding motifs and was identified as a portion of theactin-bundling protein synaptopodin. In vitro binding assays confirmedthis interaction between MAGI-1 and synaptopodin and identifiedthe second WW domain of MAGI-1 to be responsible for the interaction.MAGI-1 and synaptopodin can also interact in vivo, as they canbe immunoprecipitated together from HEK293 cell lysates. Anotheractin-bundling protein that is found in glomerular podocytes andshown to be mutated in an inheritable form of glomerulosclerosisis $alpha$ -actinin-4. We show that $alpha$ -actinin-4 is also capable of bindingto MAGI-1 in in vitro binding assays and that this interactionis mediated by the fifth PDZ domain of MAGI-1 binding to the Cterminus of $alpha$ -actinin-4. Exogenously expressed synaptopodin and $alpha$ -actinin-4 were found to colocalize along with endogenous MAGI-1at the tight junction of Madin-Darby canine kidney cells. Theinteraction and colocalization of MAGI-1 with two actin-bundlingproteins suggest that MAGI-1 may play a role in actin cytoskeletondynamics within polarized epithelialcells.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The ability of the mammalian kidney to produce a protein-free filtrate is predominantly due to specialized cells within therenal glomerulus known as visceral epithelial cells or podocytes.Mature differentiated podocytes are highly specialized cells whosemany functions, including regulating glomerular permselectivity(1), depend on an elaborate and complex cellular morphology(2). Because of this distinct morphology, podocytes can bedivided into three functionally and structurally different segments:cell body, major processes, and foot processes. Structural differencesin the segments of podocytes are reflected in their differentcytoskeletal foundation, with foot processes exhibiting an actin-basedcontractile apparatus (3). In glomerular diseases with massiveproteinuria, podocytes may undergo dramatic structural changesresulting in loss of foot process architecture and eventual effacement.Under some conditions, these changes are reversible, which illustratesthe morphological dynamics of foot processes. Although the regulationof foot process dynamics is poorly understood at this time, itis apparent that an alteration in the actin-based cytoskeletonis a fundamentalaspect.

Two actin-bundling proteins have recently drawn attention because of their expression within the podocyte. One of them, synaptopodin,was initially identified as an antigen to a monoclonal antibodythat showed association with the actin system of podocyte footprocesses (4). Its eventual cloning and characterization showedno significant homology to any other known proteins, and it wasfound in the dendritic spines of hippocampal neurons in additionto renal podocytes (5). The finding that synaptopodin associateswith specialized actin-based compartments of renal podocytes andneuronal dendrites suggests that synaptopodin may play a rolein the structural and/or functional dynamics of these cellularextensions. The non-muscle isoform of $alpha$ -actinin is another actin-associatedprotein shown to be expressed in the podocyte (3, 6, 7).Of the two known non-muscle isoforms of $alpha$ -actinin ( $alpha$ -actinin-1and $alpha$ -actinin-4), $alpha$ -actinin-4 was recently identified as the isoformthat is present in human podocytes, and mutations in the geneencoding this protein are responsible for an autosomal dominantform of focal and segmental glomerulosclerosis (FSGS)¹ in humans (8). Interestingly, both $alpha$ -actinin-1 and $alpha$ -actinin-4are found in cultured mouse podocytes, but they exhibit differencesin their spatial distribution within these cells (9). Originallyidentified as the antigen to a monoclonal antibody that exhibiteda unique immunohistochemical reactivity, $alpha$ -actinin-4 has alsobeen implicated in cell motility and carcinogenesis (10).

We recently reported on the localization of a protein, MAGI-1, in the podocytes of rat kidneys (11). In addition, we showedthat MAGI-1 was found in the membrane fraction of mouse glomerularpreparations and that it was insensitive to extraction with TritonX-100, which suggested to us that MAGI-1 might be associated withthe actin cytoskeleton. The MAGI proteins consist of three membersthat together make up a subfamily of a larger group of proteinsknown as the MAGUKs. MAGUK proteins share a common structuralorganization and are proposed to function as molecular scaffoldswithin cells (for recent reviews, see Refs. 12 and 13). Manyof them are found at special subcellular regions such as postsynapticdensities within neurons as well as the tight and adherens junctionsof epithelial cells and are believed to play a role in the structureand function of these specialized complexes. The MAGUK proteinsexhibit a unique grouping of protein-protein interaction domainsthat is inverted in the MAGI family of proteins. In addition,two WW domains in the MAGI proteins take the place of the SH3(Src homology 3) domain observed in the conventional MAGUKs. WWdomains are small protein interaction modules of 30-40 amino acidsin length and are often found in association with other proteininteraction domains such as phosphotyrosine-binding and PDZ domains(14, 15). They have been found to bind polyproline-rich peptidesequences and can be classified into five distinct groups basedupon current understanding of their binding specificity. GroupI WW domains, like those found in the ubiquitin-protein ligaseNedd4 and Yes-associated protein, have been extensively studiedand recognize "PPXY" motifs (where P is proline, X is any aminoacid, and Y is tyrosine; often referred to as PY motifs) (16,17). The binding of a number of proteins to the PDZ domainsand guanylate kinase domain of MAGI-1, MAGI-2, and MAGI-3 hasbeen reported; however, there is a paucity of data on proteinsthat may interact with the WW domains of MAGI proteins. Althougha screen to identify interacting partners for the DRPLA (dentatorubraland pallidoluysian atrophy) gene product atrophin-1 isolated partialcDNAs containing the WW domains of MAGI-1 (AIP-3) and MAGI-2 (AIP-1)(18), no further data on these interactions have yet beenreported.

In an initial attempt to discover potential binding partners for MAGI-1 that are found in renal glomeruli, we screened a cDNAexpression library made from glomerulus-enriched preparationsof mouse kidney with the WW domains of MAGI-1. Among the clonesthat were isolated was a partial cDNA coding for a region of theactin-bundling protein synaptopodin that contained both of itsPY motifs. We provide further data strengthening this interactionof synaptopodin with MAGI-1 using various binding assays and colocalizationanalysis. In addition, we examined the potential of $alpha$ -actinin-4,another actin-bundling protein whose C terminus contains a PDZdomain-binding motif, to bind to MAGI-1. We found that $alpha$ -actinin-4was also capable of binding to one of the PDZ domains of MAGI-1.Thus, two actin-bundling proteins have been found to bind to theMAGUK protein MAGI-1, and we discuss the potential relevance oftheseinteractions.

MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Plasmid Constructs-- The following MAGI-1 constructs were obtained using reverse transcription-PCR on total RNA derived from mouse glomerulus-enrichedpreparations: full-length MAGI-1 (amino acids 1-1220; numberingof all MAGI-1 constructs is based on the full-length cDNA obtainedfrom kidney and glomerular libraries previously described (11)),which contains the shorter "A" C-terminal tail as previously described(19); MAGI-1 WW12 (amino acids 219-416); MAGI-1 WW1 (amino acids219-334); MAGI-1 WW2 (amino acids 315-414); MAGI-1 PDZ123 (aminoacids 404-919); MAGI-1 PDZ234 (amino acids 607-1081); MAGI-1 PDZ45(amino acids 905-1455), which contains the "C" C-terminal tail(19); MAGI-1 PDZ4 (amino acids 905-1081); and MAGI-1 PDZ5 (aminoacids 1011-1202). The PCR products were initially cloned intothe TA cloning vector pGEM-T-Easy (Promega, Madison, WI) and thensubcloned into pGSTag (20) and pRK5-Myc (21) for productionof GST fusion proteins in bacterial cells and expression of Myc-taggedproteins in mammalian cells,respectively.

A human synaptopodin construct containing the two PPXY motifs (amino acids 294-350) was obtained by PCR of a human expressedsequence tag cDNA using forward primer 5'-CATGGTGGAAAGGAGGATGATGG-3'and reverse primer 5'-ACTTGGGGTCGGAGCTGGGATAC-3'. The PCR productwas first cloned into pGEM-T-Easy and then subcloned into pGSTagto make GST-synpoPY. A full-length mouse synaptopodin cDNA inthe expression vector pRC/CMV was subcloned into HA₃-pcDNA3.1( $-$ )(HA-synaptopodin) by PCR such that the flanking 5'- and 3'-untranslatedsequences in the original cDNA were deleted. This HA-tagged synaptopodinconstruct was further subcloned into pTRE2hyg for use in the Tet-Offinducible system. The T7 epitope-tagged mouse Nedd4 expressionconstruct (T-Nedd4) was a kind gift from Dr. D. Rotin (Hospitalfor Sick Children, Toronto, Canada). The C-terminal tail of $alpha$ -actinin-4was obtained by PCR of a rat expressed sequence tag cDNA and consistedof the last 19 amino acids including the endogenous stop codon.The $alpha$ -actinin-4 tail was cloned into pGSTag to make GST- $alpha$ -actinin-4.A full-length mouse $alpha$ -actinin-4 cDNA (a kind gift from Dr. S.R. Vincent, University of British Columbia, Vancouver, BritishColumbia, Canada) was cloned into the HA₃-pcDNA3.1( $-$ ) vector tomake HA- $alpha$ -actinin-4.

Antibodies-- Anti-Myc antibody 9E10 was obtained from mouse ascites fluid produced at the Hybridoma Core Facility of the University ofMichigan. Anti-T7 antibody (T7·Tag) was from Novagen (Madison,WI). Anti-synaptopodin polyclonal antibody NT was described elsewhere(5). Anti-MAGI-1 polyclonal antibody UM209 was described previously(11). An additional anti-MAGI-1 polyclonal antibody (UM223)was produced in rabbits using a GST fusion protein containingamino acids 905-1081 (containing the "b" variant of PDZ4 (11))of MAGI-1 and then affinity-purified. Anti-HA antibodies 3F10(rat monoclonal) and 12CA5 (mouse monoclonal) were from RocheMolecular Biochemicals. Mouse anti- $alpha$ -actinin-4 monoclonal antibodyNCC-Lu-632 was a kind gift from Dr. T. Yamada (National CancerCenter Research Institute, Tokyo, Japan). Mouse anti-ZO-1 monoclonalantibody ZO1-1A12 was from Zymed Laboratories Inc. (South SanFrancisco,CA).

Expression Cloning-- Total RNA isolated from glomerulus-enriched preparations of mouse kidneys was used to make a random-primed cDNA library, whichwas then modified at its ends with EcoRI adapters. The cDNA librarywas then cloned into $lambda$ SCREEN phage arms containing EcoRI sitesat their ends (CLONTECH, Palo Alto, CA). The library had an initialcomplexity of ~1 × 10⁶ plaque-forming units/ml prior to one round of amplification.The GST fusion protein GST-MAGI-1 WW12 (see above) was labeledwith [ $gamma$ -³²P]ATP and used as a probe to screen the library (the pGSTag expressionvector has a protein kinase A phosphorylation site placed in betweenthe GST sequence and the downstream protein of interest). Platingand transferring of plaques to nitrocellulose membranes were performedas described in the $lambda$ SCREEN manual. The resulting membranes wereblocked in Farwestern buffer (20 mM Hepes (pH 7.5), 1 mM KCl,5 mM MgCl₂, 5 mM dithiothreitol, 5% nonfat dry milk, and 0.02%sodium azide) for 2 h at room temperature with gentle agitation,followed by a 2-h incubation with the ³²P-labeled probe (2 × 10⁶ cpm/ml of Farwestern buffer) at room temperature. The membraneswere washed twice with Tris-buffered saline supplemented withTriton X-100 to 0.1% and then three times with Tris-buffered saline(5 min each wash) at room temperature. The membranes were exposedto x-ray film at $-$ 80 °C.

Cell Culture and Transfections-- HEK293 cells and MDCK cells were grown in Dulbecco's modified Eagle's medium (Invitrogen) supplemented with 10% fetal calfserum, 2 mM L-glutamine, 100 units/ml penicillin G, and 100 µg/mlstreptomycin. Tet-Off MDCK cells (CLONTECH) were grown in Dulbecco'smodified Eagle's medium supplemented with 5% fetal calf serum,4 mM L-glutamine, 100 units/ml penicillin G, 100 µg/ml streptomycin,1 µg/ml puromycin, and 40 ng/mldoxycycline.

For transient transfections, HEK293 cells at 50-80% confluency in 10-cm dishes were transfected with epitope-tagged expressionconstructs using either a calcium phosphate precipitation methodor Superfect transfection reagent (QIAGEN Inc., Valencia, CA).Cells were allowed to recover for 24-48 h prior to harvestingfor lysates. Stable cell lines of MDCK and Tet-Off MDCK cellswere obtained by transfecting them at 50% confluency in 6-cm disheswith Superfect transfection reagent. Twenty-four hours after transfection,the cells were trypsinized, and one-tenth of the volume of trypsinizedcells was transferred to 15-cm dishes containing complete mediumsupplemented with Geneticin (Invitrogen) at 600 µg/ml or hygromycinB at 200 µg/ml for the Tet-Off cells. After ~10 days in selectionmedium, colonies were isolated and subsequently assayed for expressionbyimmunofluorescence.

Tissue and Cell Lysates-- Adult mouse brains were placed in a Dounce homogenizer along with high salt Triton lysis buffer (50 mM Hepes (pH 7.5), 500mM NaCl, 1.5 mM MgCl₂, 1 mM EGTA, 10% glycerol, and 1% TritonX-100) plus protease inhibitors (Complete protease inhibitor mixturetablets, Roche Molecular Biochemicals) and homogenized with 25-30strokes. The lysates were centrifuged at 20,000 × g for 30 minat 4 °C, and the resulting supernatants were transferred to freshtubes and stored at $-$ 20 °C until used. Glomerular extracts wereprepared in radioimmune precipitation assay lysis buffer (50 mMHepes (pH 7.5), 150 mM NaCl, 1.5 mM MgCl₂, 1 mM EGTA, 10% glycerol,1% Triton X-100, 1% sodium deoxycholate, and 0.1% SDS) plus proteaseinhibitors as described previously (11).

Transiently transfected HEK293 cells were washed once with ice-cold phosphate-buffered saline (PBS), scraped in 400 µl ofTriton lysis buffer (with 150 mM NaCl), transferred to microcentrifugetubes, vortexed briefly, and incubated on ice for 10 min. Thelysates were centrifuged at 20,000 × g for 20 min at 4 °C, andthe resulting supernatants were transferred to fresh tubes andstored at $-$ 20 °C until used. Cells transfected with synaptopodinexpression constructs either alone or with other expression constructswere scraped and lysed in radioimmune precipitation assay lysisbuffer plus proteaseinhibitors.

GST Fusion Protein Precipitation (Pull-down) and Immunoprecipitations-- GST fusion proteins were produced in DH5 $alpha$ bacteria cells as previously described (21). Tissue or cell lysates were combinedwith ~10 µg of GST fusion protein bound to glutathione-agarosebeads and incubated on a rocker at 4 °C overnight. The beads werethen washed twice with ice-cold HNTG buffer (20 mM Hepes (pH 7.5),150 mM NaCl, 0.1% Triton X-100, and 10% glycerol) and once withice-cold buffer containing 20 mM Hepes (pH 7.5), 150 mM NaCl,and 0.1% Triton X-100. Forty microliters of 1× SDS sample bufferwas added to the beads and then placed at 100 °C for 5 min. Proteinseluted off of the beads were subjected to SDS-PAGE, transferredto a nitrocellulose membrane, and blotted with the appropriateprimary and horseradish peroxidase-conjugated secondary antibodiesor protein A-horseradish peroxidase. Blots were then developedwith chemiluminescence reagents (PerkinElmer Life Sciences) andexposed to x-rayfilm.

For immunoprecipitations, lysates (200-300 µl) from transfected HEK293 cells were brought up to a total volume of 1 ml withHNTG buffer and rocked overnight at 4 °C with anti-Myc antibodies.The following day, protein A-Sepharose beads were added to thesamples and rocked for an additional 2 h at 4 °C. The beads werethen washed and processed in the same manner as the GST pull-downsamplesabove.

Immunofluorescence-- Wild-type MDCK cells or stable MDCK cell lines were seeded onto Transwell filters (Corning, Inc., Cambridge, MA) and allowedto reach confluency. Cells were fixed in 4% paraformaldehyde inPBS for 15 min at room temperature and then solubilized with 1%SDS in PBS for 5 min at room temperature. Blocking was performedin 50% goat serum diluted in PBS for 2 h at 30 °C in a humidifiedchamber. Primary antibodies were diluted in 2% goat serum in PBS(PBS-G) and placed on cells overnight at 30 °C in a humidifiedchamber. The filters were washed three times with PBS-G (5 mineach wash). Fluorophore-conjugated anti-rabbit, anti-rat, or anti-mousesecondary antibodies diluted in PGS-G were incubated on the filtersfor 2 h at 30 °C in a humidified chamber. The filters were thenwashed four times with PBS-G and mounted on glass slides withProLong Antifade mounting medium (Molecular Probes, Inc., Eugene,OR). Immunofluorescence images were obtained with a confocalmicroscope.

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In an effort to identify proteins in the kidney that interact with the MAGUK protein MAGI-1, we screened a cDNA expressionlibrary made from a glomerulus-enriched preparation of mouse kidneys.The library was probed with a radiolabeled GST fusion proteincontaining both WW domains of mouse MAGI-1. Screening a totalof ~1 × 10⁶ plaque-forming units with the probe resulted in the initial isolationof 11 independent clones that survived additional rounds of selectionand purification. Sequencing of the cDNA inserts from the 11 clonesshowed that five of them represented the extreme C terminus of $beta$ -dystroglycan; four exhibited high identity to the human cDNAKIAA0989; and the last two were single isolates of WBP2 and synaptopodin,resulting in a total of four distinct protein fragments. Althoughthe inserts contain partial cDNAs, all but one of the four encodedproteins have PY motifs as expected (the protein showing a highidentity to KIAA0989 lacked a conventional PY motif). Both synaptopodinand dystroglycan are known to be present in podocytes and couldpotentially serve as in vivo binding partners for MAGI-1. However,because we have found MAGI-1 in the Triton X-100-insoluble fractionof glomerulus-enriched preparations (11), which suggests anassociation with the actin cytoskeleton, we chose to focus ourattention on synaptopodin at this time. The expression clone ofmouse synaptopodin (clone 11.2) contained a region of this proteinencompassing amino acids 255-379 and harboring two potential WWdomain-binding PY motifs. These two PY motifs are conserved inhuman synaptopodin, suggesting that they may have some physiologicalrelevance.

In parallel with the screening of the glomerular expression library, we had PCR-amplified a region of human synaptopodin containingits PY motifs (amino acids 294-350) and fused it to GST to performanalysis on proteins that could potentially bind to the WW domainsof MAGI-1. This fusion protein, GST-synpoPY, was then used ina pull-down assay with lysates from HEK293 cells expressing aMyc-tagged portion of MAGI-1 containing only its two WW domains,Myc-MAGI-1 WW12. We found that the GST-synpoPY fusion proteinwas able to pull-down Myc-MAGI-1 WW12, whereas GST alone couldnot (Fig. 1A). In addition, GST-synpoPY was also capable of pullingdown a Myc-tagged full-length MAGI-1 construct expressed in HEK293cells (Fig. 1B) as well as endogenous MAGI-1 from mouse brainlysates (Fig. 1C). The multiple bands observed for MAGI-1 in mousebrain lysates are most likely due to different forms of the proteinthat we (11) and others (19) have observed previously in brainand other tissues as well. A protein whose WW domains are verysimilar to those of MAGI-1 is the ubiquitin-protein ligase Nedd4.We expressed a T7-tagged full-length Nedd4 construct in HEK293cells and tested its ability to interact with the GST-synpoPYfusion protein. GST-synpoPY was unable to pull-down Nedd4 fromcell lysates in this assay (Fig. 1D), indicating that the PY motifsof synaptopodin do not interact with any of the three WW domainsof this Nedd4 construct. In reciprocal experiments, the GST-MAGI-1WW12 fusion protein that was used as a probe to screen the glomerularcDNA library was utilized in GST pull-down assays with lysatesfrom HEK293 cells expressing a HA-tagged full-length mouse synaptopodinconstruct. As shown in Fig. 1E, GST-MAGI-1 WW12 could pull-downHA-synaptopodin from the lysates, whereas GST alone could not.In addition, using the same assay on mouse brain lysates, we foundthat GST-MAGI-1 WW12 could pull-down endogenous synaptopodin (Fig.1F). We have observed that lysates from brain contain a form ofsynaptopodin that is much more stable than the one found in glomerularlysates; and therefore, brain lysates were used as our sourceof synaptopodin in these binding assays. These data suggest thata region in synaptopodin containing its two conserved PY motifscan interact with the WW domains in MAGI-1. Moreover, this interactionappears to be somewhat specific, as this region of synaptopodinis unable to interact with Nedd4, whose WW domains show a highdegree of similarity to those in MAGI-1.

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Fig. 1. GST pull-down assays involving MAGI-1 and synaptopodin. Lysates of HEK293 cells expressing epitope-tagged constructs of MAGI-1, synaptopodin, or Nedd4 and lysates of mouse brain were incubated with GST and the GST-synpoPY and GST-MAGI WW12 fusion proteins as indicated. The resulting blots were incubated with anti-Myc, anti-MAGI-1 (UM209), anti-T7, anti-HA, or anti-synaptopodin (NT) antibody and the appropriate secondary antibodies and then developed with chemiluminescence reagents. The following lysates were used: HEK293 cells expressing Myc-MAGI-1 WW12 (A), Myc-tagged full-length MAGI-1 (myc-MAGI-1 FL) (B), T-Nedd4 (D), and HA-synaptopodin (E) and mouse brain for endogenous (endo) proteins (C and F). Lysate lanes represent 10% of that which was used in the pull-down assays. Molecular mass markers (in kilodaltons) are indicated on the left of each panel.

Because MAGI-1 contains two WW domains and synaptopodin harbors two PY motifs that are relatively close together, it is conceivablethat both WW domains of MAGI-1 bind to the two PY motifs of synaptopodin,thereby providing an enhanced interaction, or alternatively, thatonly one WW domain of MAGI-1 is responsible for this interaction.To address this possibility, we performed a Farwestern assay usingthe WW domains of MAGI-1 together or by themselves as ³²P-labeled probes (Fig. 2A). As expected, the probe with both WWdomains of MAGI-1 bound to the GST-synpoPY fusion protein (Fig.2B, second lane). When the second WW domain of MAGI-1 was usedas a probe, nearly the same degree of binding to GST-synpoPY wasobserved (Fig. 2B, sixth lane). In contrast, the degree to whichthe first WW domain bound to GST-synpoPY was significantly lessand is most likely only residual in nature (Fig. 2B, fourth lane).None of the three probes bound to GST alone (Fig. 2B, first, third,and fifth lanes). Taken together, these data indicate that MAGI-1and synaptopodin interact with each other in a direct manner invitro and that the second WW domain of MAGI-1 specifically mediatesthis interaction.

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Fig. 2. Farwestern and co-immunoprecipitation analyses for interactions of MAGI-1 with synaptopodin. A, shown is a diagram illustrating the GST-MAGI-1 constructs used as radiolabeled probes. Filled boxes denote the WW domains of MAGI-1 and are indicated as such above each. Probe 1, GST-MAGI-1 WW12; Probe 2, GST-MAGI-1 WW1; Probe 3, GST-MAGI-1 WW2. B, 100 ng of GST (first, third, and fifth lanes) and 100 ng of GST-synpoPY (second, fourth, and sixth lanes) were resolved on a 12% SDS-polyacrylamide gel and then transferred to a nitrocellulose membrane. The membrane was cut into three strips (each strip containing a lane of GST and GST-synpoPY), which were blocked in Farwestern buffer and then incubated with separate radiolabeled probes. After washing, each strip was exposed to x-ray film at $-$ 70 °C. The probed used on each strip is indicated at the bottom of the autoradiograph. Molecular mass markers (in kilodaltons) are indicated on the left. C, lysates from HEK293 cells transiently transfected with full-length (FL) HA-synaptopodin and Myc-MAGI-1 either alone or together were incubated with anti-Myc antibodies and protein A-Sepharose beads. Proteins bound to the beads were eluted off, separated on a 7% SDS-polyacrylamide gel, and blotted onto a nitrocellulose membrane. The blot was developed with anti-Myc or anti-HA antibodies and visualized with chemiluminescence reagents. Input control lysate lanes (lower two panels) represent 5% of the amount that was used in the immunoprecipitation (IP).

To investigate whether MAGI-1 and synaptopodin interact in an in vivo situation, HEK293 cells were transfected with full-lengthexpression constructs of Myc-tagged MAGI-1 and HA-tagged synaptopodineither alone or together, and the resulting cell lysates wereused in co-immunoprecipitation assays. Using anti-Myc antibodiesto precipitate MAGI-1 from the cell lysates, we found that synaptopodinwas precipitated along with MAGI-1 in cells transfected with bothexpression constructs (Fig. 2C), indicating that these two proteinsare able to interact together incells.

We have previously shown that MAGI-1 is found in Triton X-100-insoluble fractions of mouse glomerular preparations (11),which is suggestive of MAGI-1 association with the actin cytoskeleton.Although we have not ascertained whether MAGI-1 is present inlipid rafts, the above finding that MAGI-1 interacts with theactin-bundling protein synaptopodin lends support to its actincytoskeletal association as the reason for its Triton X-100 insolubility.An additional actin-bundling protein expressed in the glomerularpodocytes is one of the non-muscle isoforms of $alpha$ -actinin, viz. $alpha$ -actinin-4. Recent data provide evidence that mutations in thegene for $alpha$ -actinin-4 cause a hereditary form of FSGS in humans.In addition, both non-muscle isoforms of $alpha$ -actinin, $alpha$ -actinin-1and $alpha$ -actinin-4, contain a consensus binding motif for PDZ domains(ESDL) at their extreme C termini. These data and observationsprovided the impetus to determine whether $alpha$ -actinin-4 could interactwith any of the PDZ domains of MAGI-1. For our initial bindingassay, the last 19 amino acids of $alpha$ -actinin-4 (Fig. 3A) were fusedto GST and used in pull-down assays with lysates of HEK293 cellsexpressing different Myc-tagged constructs of MAGI-1. The GST- $alpha$ -actinin-4fusion protein was able to efficiently pull-down full-length MAGI-1,whereas GST alone was not (Fig. 3B). Of the MAGI-1 deletion constructstested, only those with an intact fifth PDZ domain retained bindingto GST- $alpha$ -actinin-4 (Fig. 3B). We next performed the reciprocalexperiment, in which the MAGI-1 construct containing only thefifth PDZ domain was fused to GST (GST-MAGI-1 PDZ5), and usedthis fusion protein in pull-down assays with HEK293 cells expressinga HA-tagged full-length $alpha$ -actinin-4 construct. GST-MAGI-1 PDZ5was sufficient to pull-down HA- $alpha$ -actinin-4, whereas GST alonewas not (Fig. 4A). In addition, we found that GST-MAGI-1 PDZ5was able to pull-down endogenous $alpha$ -actinin-4 from lysates madefrom mouse glomerulus-enriched preparations (Fig. 4B). As withsynaptopodin and MAGI-1, we wished to explore whether $alpha$ -actinin-4and MAGI-1 could form a complex when expressed together exogenouslyin HEK293 cells. Lysates from cells expressing a Myc-tagged full-lengthMAGI-1 construct and a HA-tagged full-length $alpha$ -actinin-4 constructeither alone or together were used in immunoprecipitation assayswith anti-Myc antibodies. As shown in Fig. 4C, HA- $alpha$ -actinin-4can be precipitated along with Myc-MAGI-1 from lysates expressingboth constructs, but not from lysates expressing either constructalone. Together, these data strongly suggest that an additionalactin-bundling protein ( $alpha$ -actinin-4) is able to bind to the MAGUKprotein MAGI-1.

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Fig. 3. The cytoplasmic tail of $alpha$ -actinin-4 binds to the fifth PDZ domain of MAGI-1. A, illustration of the Myc-tagged MAGI-1 constructs used for the analysis of $alpha$ -actinin-4 binding. The different domains in MAGI-1 are indicated above the full-length (FL) construct. The amino acid sequence of the $alpha$ -actinin-4 C-terminal tail that was fused to GST is shown below the MAGI-1 constructs (the potential PDZ domain-binding motif is in boldface letters). GuK, guanylate kinase. B, lysates from HEK293 cells expressing the Myc-tagged constructs of MAGI-1 were incubated with GST or GST- $alpha$ -actinin-4 (GST- $alpha$ -act4) as described under "Materials and Methods." The resulting blots were incubated with anti-Myc primary and horseradish peroxidase-conjugated sheep anti-mouse secondary antibodies and then developed with chemiluminescence reagents. Input control lysate lanes represent 10% of the amount that was used in the pull-down assays. The Myc-tagged MAGI-1 constructs used for each pull-down assay are indicated below the appropriate blot. Molecular mass markers (in kilodaltons) are indicated on the left of each panel.

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Fig. 4. GST pull-down assays and co-immunoprecipitation of $alpha$ -actinin-4. A, lysates from HEK293 cells transiently transfected with a HA- $alpha$ -actinin-4 construct were incubated with GST alone or GST-MAGI-1 PDZ5 and processed as described under "Materials and Methods." The resulting blot was incubated with an anti-HA antibody and the appropriate horseradish peroxidase-conjugated secondary antibody. Input control lysate lanes represent 10% of the amount that was used in the pull-down assay. B, lysates from glomerulus-enriched preparations of mouse kidney were incubated with GST alone or GST-MAGI-1 PDZ5 and processed as described under "Materials and Methods." The resulting blot was incubated with an anti- $alpha$ -actinin-4 antibody (NCC-Lu-632) and the appropriate horseradish peroxidase-conjugated secondary antibody. Input control lysate lanes represent 10% of the amount that was used in the pull-down assay. Molecular mass markers (in kilodaltons) are indicated on the left of each panel. C, lysates of HEK293 cells transfected with full-length Myc-MAGI-1, full-length HA- $alpha$ -actinin-4, or both constructs were incubated with anti-Myc antibodies and protein A-Sepharose beads. Proteins bound to the beads were eluted off, separated on a 7% SDS-polyacrylamide gel, and blotted onto a nitrocellulose membrane. The blot was developed with anti-Myc or anti-HA antibodies and visualized with chemiluminescence reagents. Input control lysate lanes (lower two panels) represent 5% of the amount that was used in the immunoprecipitations (IP).

The data presented thus far using in vitro binding assays and co-immunoprecipitation analyses indicate that MAGI-1 is ableto bind to two distinct actin-bundling proteins, synaptopodinand $alpha$ -actinin-4. To further strengthen these observations, westably expressed full-length HA-synaptopodin in Tet-Off MDCK cellsand HA- $alpha$ -actinin-4 in regular MDCK cells to determine whetherthey would colocalize with endogenous MAGI-1 in the cells. Whennormal MDCK cells were stained with an antibody against MAGI-1and ZO-1, we found that there was complete colocalization of thetwo endogenous proteins (Fig. 5C), confirming the previous resultsof others (22) that MAGI-1 is a tight junction-associated proteinin these cells. MDCK cells stably expressing HA- $alpha$ -actinin-4 showeda localization pattern that was found all along the lateral membraneof most cells that extended up to and overlapped with MAGI-1 atthe tight junction (Fig. 5, H and I). This localization patternmimics the pattern observed for endogenous $alpha$ -actinin-1 in thesecells.² Because our initial attempts to express HA-synaptopodin in regularMDCK cells were unsuccessful, we chose to express this constructin the Tet-Off MDCK inducible system. When stably transfectedcells of this system are maintained in the presence of doxycycline,the construct of interest is not expressed, thereby avoiding complicationssuch as toxicity or instability observed in constitutive expressingsystems. Tet-Off MDCK cells stably transfected with HA-synaptopodinand maintained in the absence of doxycycline expressed synaptopodinin a pattern very similar to that observed with $alpha$ -actinin-4 (Fig.5, E and F). Synaptopodin was seen to partially colocalize withMAGI-1 at the tight junction of cells. The overlapping expressionof synaptopodin and $alpha$ -actinin-4 with MAGI-1 at the tight junctionsof MDCK cells supports the binding data that MAGI-1 can interactwith these two actin-bundling proteins and that these interactionsmay have some biological significance.

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Fig. 5. Colocalization of exogenously expressed $alpha$ -actinin-4 and synaptopodin with endogenous MAGI-1 in MDCK cells. Wild-type MDCK cells (A-C) and MDCK cells stably expressing HA-synaptopodin (D-F) or HA- $alpha$ -actinin-4 (G-I) were stained with an anti-MAGI-1 polyclonal antibody (A, D, and G) (green), an anti-ZO-1 monoclonal antibody (B) (red), or a rat anti-HA monoclonal antibody (E and H) (red). The merged image of each co-staining is depicted in C, F, and I. Below each X-Y panel is the X-Z plane.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

The complex morphology observed for the renal podocyte is crucial for its function in helping to establish the glomerularfiltration barrier. Although this morphology is well characterizedat the light and electron microscope level, its establishmentand regulation at the molecular level are only slowly being realized(23). We have recently shown that the MAGUK protein MAGI-1 isfound in the glomerular podocytes of rat kidneys (11). MAGI-1,like most MAGUK proteins that contain numerous protein-proteininteraction domains, is envisioned as filling a scaffolding rolein cells that would facilitate the nucleation of a multiproteincomplex. In an effort to identify proteins in the glomerulus thatinteract with MAGI-1, we screened a cDNA expression library madefrom glomerulus-enriched preparations of mouse kidneys with aprobe containing both WW domains of MAGI-1. One clone that wasisolated in this screen contained a region of synaptopodin harboringtwo PY motifs, which are potential binding sites for Group I WWdomains. Additional in vitro and in vivo binding data using full-lengthexpression constructs as well as endogenous proteins confirmedthis interaction. Therefore, two independent approaches to investigatingprotein-protein interactions reveal the direct association ofsynaptopodin with MAGI-1. We have provided additional evidencethat this interaction is biologically relevant by showing thata full-length synaptopodin exogenously expressed in MDCK cellspartially colocalized with endogenous MAGI-1 at tight junctions.Of the two WW domains present in MAGI-1, we found that the second,or C-terminal, WW domain is responsible for mediating the interactionwith synaptopodin. Although both PY motifs of synaptopodin sharethe consensus PPXY sequence at their core, we have yet to establishto which PY motif of synaptopodin MAGI-1 preferentially bindsor if both PY motifs can serve as binding sites for MAGI-1. Becausethe amino acids flanking the two core PPXY sequences of synaptopodinare quite different, they may contribute to the specificity ofthese PY motifs in binding to different WW domains. Initially,synaptopodin was found only in the neurons of the telencephalon-derivedregions of the brain and glomerular podocytes of the kidney; butmore recently, it has been found in other tissues as well (24).MAGI-1 has been found in most tissues examined (19), makingit likely that synaptopodin is a common binding partner for MAGI-1in those tissues expressing both proteins. Although this doesnot exclude the possibility that other proteins may bind to thesecond WW domain of MAGI-1 when synaptopodin is absent, to date,no other proteins have been reported to bind this protein interactiondomain of MAGI-1. With synaptopodin as a binding partner for thesecond WW domain of MAGI-1, the first WW domain would be availableto bind to a protein yet to beidentified.

The recent discovery of mutations in the gene for $alpha$ -actinin-4 that cause a hereditary form of autosomal dominant FSGS (8)provides a link between the actin cytoskeleton and disease inthe kidney. Interestingly, the FSGS-associated mutations in $alpha$ -actinin-4occur between the actin-binding domain and the first rod domainof the protein and cause an increase in $alpha$ -actinin-4 associationwith F-actin in co-sedimentation assays. These $alpha$ -actinin-4 mutationswould not be expected to affect MAGI-1 binding to $alpha$ -actinin-4,but instead would presumably increase MAGI-1 association withthe actin cytoskeleton. This increase in MAGI-1 association withthe actin cytoskeleton could have an effect on the dynamics ofactin cytoskeleton regulation by increasing the local concentrationof potential MAGI-1-binding proteins that are known to have aneffect on actin cytoskeleton dynamics (see below). We also haveshown here that $alpha$ -actinin-4 exogenously expressed in MDCK cellspartially localized at the tight junction along with MAGI-1. Inaddition, we have observed endogenous $alpha$ -actinin ( $alpha$ -actinin-1)in MDCK cells to be localized all along the lateral membrane borderstretching up to and overlapping with the tight junction, as isseen with $alpha$ -actinin-4. Of the 19 amino acids from $alpha$ -actinin-4that were used as a GST fusion protein in this study, 18 are identicalto the other non-muscle isoform $alpha$ -actinin-1, including the PDZdomain-binding motif. It was not surprising therefore to findthat a GST fusion protein containing only the fifth PDZ domainof MAGI-1 was able to pull-down endogenous $alpha$ -actinin-1 from lysatesof HEK293 cells (data not shown). MAGI-1 appears to be capableof binding to both non-muscle isoforms of $alpha$ -actinin. Our previousresults showing MAGI-1 in the Triton X-100-insoluble fractionof membranes from mouse glomerular preparations suggests a cytoskeletalassociation of MAGI-1 (11). Alternatively, this observed insolubilitycould also be due to the association of MAGI-1 with detergent-resistantmicrodomains, or lipid rafts. However, our finding of MAGI-1 interactionwith the two actin-binding proteins $alpha$ -actinin and synaptopodinsuggests an association with the actin cytoskeleton as the reasonfor its resistance to extraction with Triton X-100.

Although the distinct subcellular localization of MAGI proteins in tissues is somewhat limited at this time, MAGI-1 was foundlocalized at the tight junctions in intestinal epithelium usingimmunoelectron microscopy (22). It was also shown that the localizationof endogenous MAGI-1 in MDCK cells overlaps perfectly with thelocalization of the tight junction protein ZO-1, a finding thatwe confirmed in this study. Our data provide additional evidencethat MAGI-1 provides a link from membrane-associated protein complexesto the actin cytoskeleton in epithelial cells by way of its interactionwith $alpha$ -actinin and/or synaptopodin. This indirect associationof MAGI-1 with the actin cytoskeleton appears to be an increasinglyevident phenomenon among MAGUK proteins. For example, the humanhomolog of Drosophila DLG (discs large) and CASK bind to protein4.1, a member of the FERM protein family that binds to actin (25,26). Moreover, a direct association with the actin cytoskeletonis seen with the MAGUK protein ZO-1 (27).

It is apparent that the morphological changes observed in the foot processes of podocytes in the nephrotic syndrome are dependenton the reorganization of the actin-based cytoskeleton. Understandingthe regulation of the actin cytoskeleton in podocytes is thereforecrucial. The finding of MAGI-1 at membrane-associated complexesin epithelial cells suggests a model in which MAGI-1 would belocalized at the membrane of foot processes and tethered to theactin cytoskeleton by way of its interaction with synaptopodinand $alpha$ -actinin-4. Although the localization of MAGI-1 in podocytesat the ultrastructural level is not currently available, we feelthat MAGI-1 could be localized in a manner that would at leastpartially overlap with synaptopodin and $alpha$ -actinin-4. In additionto actin and $alpha$ -actinin, the microfilament contractile apparatusof podocyte foot processes is also composed of myosin II, talin,and vinculin, which extends down to and is linked with the glomerularbasement membrane by an $alpha$ ₃ $beta$ ₁ integrin- and $alpha$ / $beta$ -dystroglycan-basedelectron-dense protein complex called the sole plate (3, 28,29). Like the localization of $alpha$ -actinin at integrin-based proteincomplexes in cultured cells, $alpha$ -actinin-4 is observed to be partiallylocalized at the sole plate (3, 30). Although $alpha$ -actinin-4itself can provide a link from the sole plate protein complexto the actin cytoskeleton, its interaction with MAGI-1 would providean additional link to the actin microfilament array via synaptopodin.Alternatively, it is plausible that MAGI-1 is providing a platformfor regulators of actin dynamics in the foot process instead ofmerely playing an additional passive structural link between theactin cytoskeleton and the membrane. It is well established thatintegrin-based focal contacts in cell culture provide a signalinglink from the substrate-contacting plasma membrane to the actincytoskeleton and are regulated by the Rho family of small GTPases.Interestingly, the guanine nucleotide exchange factor mouse NET1has recently been identified as a binding partner for the firstPDZ domain of MAGI-1 (31). Mouse NET1 activates RhoA and thestress-activated protein kinase/c-Jun N-terminal kinase signalingpathways (32). RhoA activation stimulates actomyosin-based contractility,which contributes to the assembly of stress fibers and focal contacts(33, 34). Additionally, the tumor suppressor PTEN has beenshown to bind to the second PDZ domain of all three MAGI proteins(35, 36) and is implicated in focal contact assembly by antagonizingthe phosphatidylinositol 3'-kinase signaling pathway. However,the precise localization of mouse NET1 and PTEN within the kidneyis not known at thistime.

The precise mechanism by which MAGI-1 associates with distinct plasma membrane subdomains or what function it may serve thereis speculative at this time. Expression of the last two PDZ domains(PDZ4 and PDZ5) of MAGI-1 as a GFP fusion protein in normal ratkidney cells is sufficient to target the fusion protein to thelateral plasma membrane (37). Furthermore, when a mutant MAGI-1construct that lacks its fifth PDZ is expressed in MDCK cells,the mutant protein no longer is found in the membrane fraction,as is the wild-type protein, but is instead exclusively observedin the cytosolic fraction (38). We have generated a point mutationin the fifth PDZ domain of MAGI-1 that abolished binding of cognateligands to this domain and expressed this in the context of thefull-length MAGI-1 protein within MDCK cells. This MAGI-1 mutantexhibited neither tight junction nor plasma membrane localizationcompared with the wild-type protein and was found throughout thecell (data not shown). This confirms that the fifth PDZ domainis required for proper localization of MAGI-1 to the plasma membrane,but it is not clear if the fifth PDZ domain alone is sufficientto properly target MAGI-1 to the tight junction of MDCK cellsonce it is at the membrane. We are not sure at this time whetherthe interaction of MAGI-1 with $alpha$ -actinin-4 (or other proteinsknown to bind to the fifth PDZ domain of MAGI-1) is solely responsiblefor the plasma membrane localization of MAGI-1 in MDCK cells.We are currently investigating the potential involvement of theother protein interaction domains of MAGI-1 regarding their rolein proper membranelocalization.

The identification of the proteins in renal podocytes and other cells that bind to MAGI-1, whether they are integral transmembraneproteins or peripheral proteins, will undoubtedly help revealthe function of MAGI-1. This proteomic approach combined withtransgenic technology will help provide an understanding of therole that MAGUK proteins play in the function and regulation ofpodocytedynamics.

ACKNOWLEDGEMENTS

We thank Chia-Jen (Albert) Liu for expert assistance with the confocal microscopy work, Dr. Daniela Rotin for the T-Nedd4cDNA construct, Dr. Steven R. Vincent for the $alpha$ -actinin-4 cDNA,and Dr. Tesshi Yamada for the anti- $alpha$ -actinin-4 monoclonal antibodyNCC-Lu-632.

	FOOTNOTES

^* This work was supported in part by NIDDK Grant 2P50DK39255 from the National Institutes of Health.The costs of publicationof this article were defrayed in part by the payment of page charges.The article must therefore be hereby marked "advertisement" inaccordance with 18 U.S.C. Section 1734 solely to indicate thisfact.

^§ Supported by National Kidney Foundation Postdoctoral Research Fellowship 5F32DK09912-02.

^¶ Present address: Sangstat Medical Corporation, 6300 Dumbarton Circle, Fremont, CA94555.

^** Supported by National Institutes of Health Grant DK57683-01.

^¶¶ Investigator of the Howard Hughes Medical Institute. To whom correspondence should be addressed: Howard Hughes Medical Inst.,University of Michigan, 4570 MSRB II, 1150 West Medical CenterDr., Ann Arbor, MI 48109-0650. Tel.: 734-764-3567; Fax: 734-763-9323;E-mail: bmargoli@umich.edu.

Published, JBC Papers in Press, May 31, 2002, DOI 10.1074/jbc.M203072200

² K. M. Patrie and B. Margolis, unpublisheddata.

ABBREVIATIONS

The abbreviations used are: FSGS, focal and segmental glomerulosclerosis; MAGI-1, membrane-associated guanylate kinase inverted-1; MAGUK, membrane-associated guanylate kinase; PDZ, PSD-95/DLG/ZO-1; AIP, atrophin-1-interacting protein; GST, glutathione S-transferase; HA, hemagglutinin; HEK293, human embryonic kidney 293; MDCK, Madin-Darby canine kidney; PBS, phosphate-buffered saline.

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