SAP97 interacts with Kv1.5 in heterologous expression systems

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SAP97 interacts with Kv1.5 in heterologous expression systems

Mitsunobu Murata, Peter D. Buckett^*, Jun Zhou^*, Michael Brunner, Eduardo Folco, and Gideon Koren

Cardiovascular Division, Brigham and Women's Hospital, Harvard Medical School, Boston, Massachusetts 02115

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

PDZ domain-containing proteins such as SAP97 and ZO-1 have been implicated in the targeting and clustering of ion channels.We have explored the interactions of these polypeptides with acardiac voltage-gated potassium channel. Immunocytochemistry incardiac myocytes revealed colocalization of SAP97 and Kv1.5, bothat the intercalated disks and the lateral membranes. Transienttransfection experiments in COS-7 cells revealed that SAP97 andKv1.5 polypeptides formed perinuclear clustered complexes thatcould be coimmunoprecipitated. Mutation of the three COOH-terminalamino acid residues of Kv1.5 (T-D-L to A-A-A) abolished theseinteractions. Whereas in most COS-7 cells the SAP97-Kv1.5 complexeswere retained in the ER, functional analyses in Xenopus oocytesshowed that Kv1.5-encoded outward potassium currents were augmentedby coexpression with SAP97. By contrast, cotransfected ZO-1 andKv1.5 polypeptides in COS-7 cells could not be coprecipitatednor did the coinjection of ZO-1 augment the Kv1.5-encoded currentsin oocytes. Collectively, our results suggest that SAP97 may playan important role in the modulation of Kv1.5 channel functionin cardiacmyocytes.

cardiac myocytes; K⁺ channels; ZO-1

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

THE ELECTRICAL PROPERTIES of cardiac myocytes are determined to a large extent by the expression of voltage-gated potassiumchannels. The organization of these channels on the cell surfaceand their subcellular localization allow cells to increase theefficiency of their response to extracellular signals. More than70 PSD-95/Dlg/ZO-1 (PDZ) domain-containing proteins have beendescribed and their interactions with membrane receptors, ionchannels, and other signaling proteins have been elucidated (11).The name PDZ derives from the three proteins that contain thisdomain: the mammalian postsynaptic density protein-95 kDa (PSD-95),the Drosophila disk large tumor suppressor Dlg, and the mammaliantight junction protein ZO-1 (12, 21). Proteins possessingPDZ domains frequently contain other interaction modules, suchas the SH3 domain. Hence, these proteins serve as a scaffold forthe assembly of different polypeptides into macromolecular signalingcomplexes. Shaker-type potassium channels and N-methyl-D-aspartate(NMDA) receptors have been identified as proteins that interactwith the PDZ domains of PSD-95 (17, 28, 34). These investigatorscharacterized a short COOH-terminal end motif (tS/T-X-V), whichis necessary for the binding of NMDA receptors and Shaker-likechannels to PDZ domains. The binding to PDZ domains determinesthe subcellular localization and the clustering of these polypeptidesin neurons (14, 15, 17). Additional members of the PSD-95family have been implicated in the formation of synaptic complexes(4, 5, 16, 27).

Of the different channel types expressed in cardiac myocytes, potassium channels are the most diverse. These channels participatein determining the resting membrane potential, the action potentialduration, the duration of the refractory period, and the automaticity(9). The regional and cell-specific distribution of these channelscontributes to regional variations in shape and duration of theaction potential in the heart (2, 9). Very little is knownabout the mechanisms that regulate the targeting of cardiac Kvchannels to specific sites of the plasma membrane. Two recentstudies addressed the membrane distribution of these polypeptides.Mays et al. (26) showed that Kv1.5 was localized to the intercalateddisks of human atrial and ventricular myocytes. Barry et al. (3)showed a clear membrane distribution of Kv1.5, Kv1.2, Kv2.1, andKv4.2 channel polypeptides with high staining intensity at theintercalated disks of rat cardiocytes. However, in contrast withneuronal cells, the mechanisms underlying the targeting and localizationof Kv channels to the intercalated disks of cardiac myocytes havenot been elucidated. Here we show that SAP97 colocalizes withKv1.5 channel polypeptides in cardiac myocytes. It also coprecipitatesand colocalizes with it in a COS-7 cell heterologous expressionsystem. Furthermore, SAP97 enhances Kv1.5-encoded currents incoinjection experiments using Xenopus oocytes. The results suggestthat SAP97 may play an important role in determining the plasmamembrane expression and distribution of Kv1.5 in cardiacmyocytes.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Cloning, cell culture, and transfection. Rat SAP97 cDNA was subcloned into pCDNA3 as an EcoRI/EcoRI fragment and ZO-1 cDNA was subcloned into pCDNA3 as an EcoRI/ApaIfragment. Kv1.1 (20) and Kv1.5 (24) cDNAs were subcloned asHindIII/BamHI or BstEIV/ApaI fragments in pCDNA3 with a FLAG tagat the NH₂ terminus. The FLAG epitope-tagged Kv1.5 A-A-A (FL-Kv1.5-A)mutant was generated by polymerase chain reaction (PCR) usingthe following primers: forward, 5'-GCCGATCCATTCTTCATCGTGGAGACC-3';and reverse, 5'-CGCGGATCCTTACGCAGCAGCTTCACGGCTAGTGTCCAG-3'; anda 0.75-kb ClaI/BamHI fragment from the PCR product was used toreplace an equivalent fragment in wild-type FL-Kv1.5 cDNA. COS-7cells were cultured in Dulbecco's modified Eagle's medium containing10% fetal calf serum at 37°C in a 5% CO₂ incubator. Transienttransfection experiments were performed as described previously(23).

Immunocytochemistry. Adult rat ventricular myocytes were prepared as described previously (35). Freshly isolated cardiocytes or COS-7 cells werefixed and permeabilized in 2% paraformaldehyde and 0.5% saponinin phosphate-buffered saline (PBS) (pH 7.4) for 30 min. The cellswere postfixed in a 1:1 methanol-acetone mixture for 10 min andblocked with 5% BSA for 1 h. Cells were dual labeled with theprimary antibodies in a sequential manner. The antibodies usedwere mouse monoclonal anti-PSD-95 family (Upstate Biotechnology),which may recognize several PDZ domain-containing proteins, includingPSD-95, SAP-97, and chapsyn/PSD-93, affinity-purified rabbit polyclonalanti-SAP97 (a kind gift of Dr. M. Sheng), rabbit polyclonal anti-Kv1.5(1), mouse monoclonal anti-BiP (Transduction Laboratories),and mouse monoclonal anti-N-cadherin (Transduction Laboratories).The secondary antibodies used were fluorescein isothiocyanate-conjugatedgoat anti-mouse or anti-rabbit and rhodamine-conjugated donkeyanti-mouse or anti-rabbitIgGs.

Immunoprecipitation. Three to four days after the transfections, COS-7 cells were harvested with the use of a lysis buffer composed of (in mM)150 NaCl, 10 Tris (pH 8.0), 0.5 EDTA, 1 iodoacetamide, and 1%Triton X-100 and a mixture of protease inhibitors. The immunoprecipitationexperiments were carried out as described previously (23). Theimmunopellets were electrophoresed in 8% sodium dodecyl sulfate-polyacrylamidegels (SDS-PAGE), blotted onto PVDF membranes, and probed withthe following antibodies: anti-PSD-95, anti-SAP97, rabbit polyclonalanti-ZO-1 antibody (Zymed), rabbit polyclonal anti-Kv1.5 antibody,or mouse monoclonal anti-FLAG (Sigma). Crude membrane and cytosolfractions were prepared from mouse heart ventricles by differentialcentrifugation. With the use of a Polytron, ventricles were homogenizedin Tris-EDTA buffer (pH 7.4) with 1 mM iodoacetamide and a cocktailof protease inhibitors. Debris was pelleted by centrifugationat 1,000 g and the supernatant was spun at 40,000 g for 1 h. Thecrude membrane pellet was washed once and dissolved in Tritonlysisbuffer.

Electrophysiological studies. Xenopus oocytes were harvested from mature Xenopus laevis females and dissociated in Ca²⁺-free Barth's solution containing 1 mg/ml type II collagenase(Worthington). Isolated follicle-free stage 5 and 6 oocytes wereselected and injected with different amounts of cRNAs. For coexpressionexperiments, Kv1.5 cRNA was mixed with either SAP97 or ZO-1 cRNAsbefore injections. The total volume of the cRNAs injected wasconstant (46 nl) in each group to minimize the variation resultingfrom on-site leakage. The injected oocytes were maintained at18-19°C in Barth's solution. The Barth's solution, supplementedwith penicillin (100 U/ml) and streptomycin (100 µg/ml), contained(in mM) 88 NaCl, 1.0 KCl, 2.4 NaHCO₃, 0.3 Ca(NO₃)₂, 0.41 CaCl₂,0.82 MgSO₄, 15 HEPES, and 5 sodium pyruvate, pH 7.6. Kv1.5-encodedcurrents were measured with a two-microelectrode voltage clampusing a GeneClamp amplifier (model 500, Axon Instruments) controlledby pCLAMP software (version 6.0.4, Axon Instruments) through aDigidata interface (model 1200, Axon Instruments). The bath solutioncontained (in mM) 96 NaCl, 2 KCl, 0.5 CaCl₂, 0.5 MgCl₂, and 10HEPES, pH 7.5. Currents were elicited by a series of depolarizationpulses from the holding potential of $-$ 70 to +60 mV with an incrementof 10 mV for 200 ms, followed by a repolarization to $-$ 40 mV toelicit the tail currents. A P/4 leakage substraction protocolwas used to minimize the leakage and capacitative currents. Datawere expressed as means ± SD. Student's t-test and analysis ofvariance were used to evaluate the statisticalsignificance.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Colocalization of SAP97 and Kv1.5 in cardiac myocytes. The involvement of PSD-95 and other PDZ domain-containing proteins in the assembly of macromolecular signaling complexes inneurons has been clearly established. By contrast, very littleis known about the formation, molecular composition, and targetingof signaling complexes containing K⁺ channels in cardiac tissue. SAP97, a PDZ domain-containing proteinabundantly expressed in the heart, was shown to interact withShaker-like K⁺ channels in heterologous systems. We used immunocytochemistryto study the membrane distribution of SAP97 and Kv1.5 in cardiacmyocytes using anti-SAP97, anti-PSD-95, and anti-Kv1.5 antibodies.Control experiments using preimmune serum, rabbit IgG, isotype-specificmouse IgG, or secondary antibodies did not show significant stainingunder the experimental conditions used. Experiments using affinity-purifiedanti-SAP97 antibody revealed that SAP97 is expressed at both theintercalated disks and the lateral membranes (Fig. 1A). A similardistribution was observed using the monoclonal anti-PSD-95 antibody(Fig. 1K), although the background staining with this antibodywas higher. The distribution pattern of SAP97 differed from thatof ZO-1, another PDZ domain-containing protein expressed in theheart: ZO-1 localized primarily to the intercalated disks, withno staining detectable in lateral membranes (not shown). Moreimportantly, the staining with anti-Kv1.5 antibody revealed thatthe membrane distribution of this channel was similar to thatof SAP97: the immunoreactive Kv1.5 polypeptide was detectableboth at the intercalated disks and the lateral membranes (Fig.1D). To further prove that the distribution of Kv1.5 and SAP97includes both the intercalated disks and the lateral membrane,we costained cardiac myocytes with anti-N-cadherin and eitheranti-Kv1.5 or anti-SAP97 antibodies. The results showed that,whereas the N-cadherin antibody stained only the intercalateddisks (Fig. 1, B, E, and H), SAP97 and Kv1.5 immunoreactive polypeptideswere detected both in the intercalated disks and lateral membranes(Fig. 1, A, C, D, and F). Interestingly, Z-series confocal microscopyrevealed a patchy distribution of Kv1.5 on the cell surface thatclearly differs from that of N-cadherin (Fig. 1, G-I). To furtherprove the colocalization of SAP97 and Kv1.5, we performed costainingexperiments using rabbit polyclonal anti-Kv1.5 and mouse monoclonalanti PSD-95 antibodies. The results (Fig. 1, J-L) confirmed thecolocalization of Kv1.5 and SAP97 in cardiac myocytes. Althoughanti-PSD95 cross-reacts with additional PDZ domain-containingproteins, we had to use this antibody because the monoclonal anti-Kv1.5antibody failed to detect Kv1.5 in cardiac myocytes. Taken together,these experiments revealed codistribution of Kv1.5 and SAP 97in the lateral membranes and the intercalated disks.

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Fig. 1. Confocal images of FLAG epitope-tagged Kv1.5 (FL-Kv1.5) and SAP97 in adult rat cardiac myocytes. Cells were reacted with rabbit anti-SAP97 (A), rabbit anti Kv1.5 (D, G, and J), mouse anti-postsynaptic density-95 (PSD-95) (K), and mouse anti-N-cadherin (B, E, and H) antibodies. C, F, I, and L are superimpositions of the images in A and B, D and E, G and H, and J and K, respectively. The mouse anti-PSD-95 antibody may recognize several PSD-95/Dlg/ZO-1 (PDZ) domain-containing proteins, including PSD-95, SAP97, and chapsyn/PSD-93.

Biochemical and immunocytochemical evidence for interactions of FL-Kv1.5 with SAP97. We then investigated whether SAP97 and Kv1.5 interact in vivo. We were unable to consistently detect this interaction in coimmunoprecipitationexperiments from heart extracts, presumably because of the lowlevel of expression of Kv1.5. Thus we decided to examine the Kv1.5-SAP97interaction in overexpression experiments in COS-7 cells, usingSAP97 and NH₂-terminal FL-Kv1.5 cDNAs subcloned into pCDNA3. Initially,the cells were transfected with SAP97 cDNA and the cell lysateswere precipitated with anti-PSD-95 family antibody (anti-PSD-95).To determine the specificity of this antibody in COS-7 cells,the immunoprecipitates were size separated and immunoblotted witheither anti-PSD-95 or an affinity-purified rabbit polyclonal anti-SAP97antibody. Anti-PSD-95 antibody reacted with two ~120-kDa polypeptidesin transfected COS-7 cells (Fig. 2A, lane 2), but it did not reactwith the ZO-1 polypeptides (Fig. 2A, lane 3). Importantly, affinity-purifiedanti-SAP97 antibody reacted with the same two 120-kDa polypeptides(Fig. 2A, lane 5), confirming the observation of Kim et al. (16)that SAP97 cDNA transfected into COS-7 cells codes for polypeptideswith an apparent molecular mass of 120 kDa. The second band islikely due to posttranslational modifications of SAP97. Westernblot analysis of cardiac cell lysates revealed that anti-PSD-95antibody also reacted with two polypeptides with apparent molecularmass of ~120 kDa, identical to those of SAP97 expressed in COS-7cells (Fig. 2B, lanes 1-3). Differential centrifugation of heartextracts revealed that most of the SAP97 polypeptides segregatedto the crude membrane fraction (Fig. 2C, lane 2) rather than thecytosol (Fig. 1C, lane 1).

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Fig. 2. The expression of SAP97 in transfected COS-7 cells and mouse heart detected by PSD-95 antibody. A: COS-7 cells were transfected with either vector alone (pCDNA3; lanes 1 and 4), SAP97 (lanes 2 and 5) or with ZO-1 (lanes 3 and 6) cDNAs. Cell lysates were reacted with anti-PSD-95 antibody for immunoprecipitation. The precipitates were immunoblotted with either anti-PSD-95 antibody (left) or anti-SAP97 antibody (right). B: crude cardiac myocyte lysates [20 µg (lane 1), 40 µg (lane 2), and 80 µg (lane 3)] were electrophoresed on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and immunoblotted with anti-PSD-95 antibody. C: Western blot analysis of SAP97 in cytosol and membrane fractions from mouse heart. The fractions were prepared by differential centrifugation.

We then tested whether SAP97 interacts with FL-Kv1.5 in cotransfection experiments of COS-7 cells. The cell lysates were firstreacted with anti-Kv1.5 antibody. The immunoprecipitates werethen size separated using SDS-PAGE and immunoblotted with anti-PSD-95,anti-Kv1.5, and anti-FLAG antibodies. The results (Fig. 3A) showedthat anti-Kv1.5 antibody could immunoprecipitate a polypeptidewith an apparent molecular mass of 70 kDa that reacted with bothanti-Kv1.5 and anti-FLAG antibodies in immunoblot assays (Fig.3A, middle and bottom, lanes 3 and 4). The mobility of the Kv1.5polypeptide expressed in COS-7 cells is faster than that expressedin the heart (or in GH3 cells), which most likely indicates differentposttranslational modifications. Indeed, immunocytochemical studiesin COS-7 cells (see below) indicated that most of the Kv1.5 polypeptidesremained in the endoplasmic reticulum (ER) and therefore couldnot complete the biosynthetic pathway that occurs in either GH3cells or the heart. Importantly, anti-Kv1.5 antibody coprecipitatedtwo polypeptides with an apparent molecular mass of 120 kDa thatreacted with anti-PSD-95 antibody in immunoblot assays (Fig. 3A,top, lane 4). In the absence of cotransfected SAP97, the anti-Kv1.5antibody did not precipitate these polypeptides (Fig. 3A, lanes1-3). Anti-FLAG antibody could also coprecipitate SAP97 and Kv1.5complexes (see Fig. 4A). To confirm these interactions betweenKv1.5 and SAP97, lysates from cotransfected COS-7 cells were firstreacted with anti-PSD-95 antibody, and the precipitates were thensize separated using SDS-PAGE and immunoblotted with anti-Kv1.5and anti-FLAG antibodies. The results revealed that anti-PSD-95could coprecipitate a 70-kDa polypeptide that reacted in immunoblotassays with anti-Kv1.5 and anti-FLAG antibodies only in the presenceof cotransfected SAP97 (Fig. 3B, lane 4) and not in its absence(Fig. 3B, lanes 1 and 3). In contrast to the observed interactionof SAP97 with Kv1.5, the cotransfection of ZO-1 with either FL-Kv1.5or FL-Kv1.1 into COS-7 cells did not result in the coimmunoprecipitationof ZO-1 polypeptides with anti-FLAG antibody (Fig. 3C, in lanes1 and 2), although both ZO-1 and FL-Kv channels were detectablein the COS-7 lysates (Fig. 2C, lanes 3 and 4). Thus ZO-1 doesnot interact directly with either FL-Kv1.5 or FL-Kv1.1 polypeptidesin this system.

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Fig. 3. Coimmunoprecipitation assays from lysates of COS-7 cells cotransfected with SAP97 and FL-Kv1.5. A: COS-7 cells were transfected with vector alone (pcDNA3; lane 1), SAP97 (lane 2), FL-Kv1.5 (lane 3), or SAP97 and FL-Kv1.5 (lane 4) cDNAs. Half of the cell lysates were reacted with anti-Kv1.5 antibody (AK1.5). The proteins were immunoblotted with 0.5 µg/ml anti-PSD-95 (top) and with either anti-Kv1.5 (1:2,500 dilution) (middle) or anti-FLAG (10 µg/ml) antibodies (bottom). B: remaining half of the cell lysates were immunoprecipitated with anti-PSD-95 antibody and blotted with anti-Kv1.5 (top), anti-FLAG (middle), and anti-PSD-95 (bottom) antibodies. Molecular mass standards are shown in kilodaltons. C: COS-7 cells were transfected with either ZO-1 and FL-Kv1.1 (lanes 1 and 3) or ZO-1 and FL-Kv1.5 (lanes 2 and 4). Cell lysates were then precipitated with anti-FLAG antibody (lanes 1 and 2; IP with anti-FLAG). Lanes 3 and 4 were directly loaded with the transfected cell lysates (Lysates). The membrane was then blotted with anti-ZO-1 (1:2,000 dilution) (top) and anti-FLAG (bottom) antibodies.

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Fig. 4. Coimmunoprecipitation assays from lysates of COS-7 cells cotransfected with SAP97 and either FL-Kv1.5 or FLAG epitope-tagged Kv1.5 A-A-A (FL-Kv1.5-A). A: COS-7 cells were transfected with vector alone (pCDNA3; lane 1), FL-Kv1.5 (lane 2), FL-Kv1.5-A (lane 3), FL-Kv1.5 and SAP97 (lane 4), FL-Kv1.5-A and SAP97 (lane 5), or SAP97 alone (lane 6). Half of the cell lysates were reacted with anti-FLAG antibody and the proteins were immunoblotted with 0.5 µg/ml anti-PSD-95 (top) or 10 µg/ml anti-FLAG (bottom) antibodies. B: the remaining half of the cell lysates was immunoprecipitated with anti-PSD-95 antibody and blotted with anti-FLAG (top) or anti-PSD-95 (bottom) antibodies. Molecular mass standards are shown in kilodaltons.

The association of PSD-95 with Shaker-like channels or NMDA receptors occurs through the interaction of the first two PDZdomains of PSD-95 with a short motif (tT/S-X-V) located at theCOOH-terminal end of the channel or receptor proteins. Thus, tofurther characterize the specificity of the interaction of SAP97with Kv1.5, we mutated the three COOH-terminal amino acid residuesof Kv1.5 (T-D-L) to A-A-A (FL-KV1.5-A). Cotransfection experimentsof FL-Kv1.5 or FL-Kv1.5-A with SAP97 in COS-7 cells showed thatanti-FLAG antibody was able to coprecipitate SAP97 when cotransfectedwith FL-Kv1.5 (Fig. 4A, top, lane 4) but not with FL-Kv1.5-A (Fig.4A, top, lane 5). Similarly, anti PSD-95 antibody was able tocoprecipitate FL-Kv1.5 (Fig. 4B, top, lane 4) but not FL-Kv1.5-A(Fig. 4B, top, lane 5) with SAP97 in cotransfection experimentsin COS-7 cells (Fig. 4B). Collectively, these results indicatethat the T-D-L sequence located at the COOH terminus of Kv1.5is critical for its interaction withSAP97.

We then used immunocytochemistry to further describe these complexes. The results show that the transient transfection ofFL-Kv1.5 cDNA into COS-7 cells resulted in a diffuse intracellularreticular staining, a pattern characteristic of proteins locatedin the endoplasmic reticulum, with minimal linear accumulationon the cell membrane (Fig. 5A) (10). Only 20.4 ± 1.0% (n = 3)of the cells exhibited membrane staining. Indeed, costaining withanti-BiP antibody confirmed that most of the Kv1.5 polypeptidescolocalized with this ER resident protein (Fig. 5, B and C), whoselevel of expression was higher in transfected than in nontransfectedcells (not shown). The transfection of SAP97 cDNA alone revealedsimilar codistribution of SAP97 with BiP (Fig. 5, D-F). Untransfectedcells showed low background fluorescence. The coexpression ofKv1.5 and SAP97 resulted in only a slight increase in the relativeamount of cells showing membrane staining (29.3% ± 3.1, n = 3;P = not significant) but did not change the ER localization ofthe bulk of Kv1.5 and SAP97 proteins (Fig. 5, G-I). These resultsare similar to the observations of Tiffany et al. (32), whichshowed that the interactions of SAP97 and Kv1.2 occurred in theER and attenuated the membrane expression of Kv1.2 and other Kv1polypeptides. However, in contrast with Kim et al. (18), weobserved a plaquelike distribution of SAP97 even in the absenceof cotransfected Kv1.5 (Fig. 5E), indicating that Kv1.5 is notessential for the formation of these plaques. Our observations,and those of Tiffany et al. (32), suggest that SAP97 associateswith Kv1.5 in the ER and does not promote significant additionaltrafficking of Kv1.5 to the membrane in COS-7 cells.

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Fig. 5. Confocal images of FL-Kv1.5 and SAP97 in transfected COS-7 cells. COS-7 cells were transfected with FL-Kv1.5 (A-C), SAP97 (D-F), or both (G-I) cDNAs. Three days after transfection, the cells were reacted with rabbit anti-Kv1.5 (A and H), mouse anti-PSD-95 (E and G), and mouse anti-BiP (B and D) antibodies. C, F, and I are superimpositions of the images in A and B, D and E, and G and H, respectively.

Coexpression of SAP97 and FL-Kv1.5 enhances Kv1.5-encoded currents in Xenopus oocytes. We next investigated the functional effects of the interaction of SAP97 and Kv1.5. Transient transfection experiments in COS-7cells are not adequate for this purpose because of the impossibilityof accurately determining the SAP97/Kv1.5 expression ratio ineach cell. Also, most of the SAP97 and Kv1.5 polypeptides areretained in the ER and thus are not suitable for electrophysiologicalstudies. Therefore, to assess the functional effects of the interactionof SAP97 and Kv1.5, we carried out coinjection experiments ofFL-Kv1.5 with either SAP97 or ZO-1 cRNAs into Xenopus oocytes.To ensure the validity of the results, we first measured the amplitudeof the Kv1.5-encoded outward currents in oocytes injected with4 (not shown), 8, and 16 fmol of FL-Kv1.5 cRNAs. As shown in Fig.6A, the linearity of the current was maintained fairly well atdifferent voltages with the amount of cRNA tested. Based on theseresults, 8 fmol of FL-Kv1.5 cRNA was used in coinjection experiments.Oocytes injected with FL-Kv1.5 cRNA expressed rapidly activatingand slowly inactivating outward potassium current (Fig. 6B). Coinjectionof SAP97 with FL-Kv1.5 resulted in a statistically significanttwofold increase in the steady-state levels of the Kv1.5-encodedcurrents (Fig. 6, B and C). A similar increase was observed intwo additional batches of oocytes coinjected, respectively, with2:4 and 4:4 fmol of Kv1.5 to SAP97 cRNAs. However, in one batchof oocytes, which expressed exceptionally high levels of currents,the coinjection of SAP97 at 4:8 and 8:8 fmol failed to enhancethe Kv1.5-encoded currents, although the 4:4 ratio did. Thus itappears that the enhancing effect of SAP97 is sensitive to theinitial level of expression of Kv1.5: the lower the Kv1.5-encodedcurrents, the more pronounced the enhancing effect. In all coinjectiongroups, the maximum relative conductance (G/G_max, Fig. 5D), voltagedependence, and kinetics of activation (data not shown) of thecurrents remained similar to those of the control group. In contrastwith the observed effect of SAP97, the coinjection of ZO-1 cRNAcaused either no change or even a slight decrease in the amountof Kv1.5-encoded currents (Fig. 6, B and C). These results, whichare in agreement with the lack of interaction of ZO-1 with Kv1.5in transfection experiments (see above), suggest that SAP97, butnot ZO-1, is able to modulate the expression of Kv1.5.

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Fig. 6. Augmentation of Kv1.5-encoded currents by coinjection of SAP97 cRNA into Xenopus oocytes. A: doubling the amount of the injected FL-Kv1.5 cRNA resulted in a twofold increase in the amplitude of the Kv1.5-encoded currents. Data are shown as means ± SD (n = 5 for the 8 fmol group and 3 for the 16 fmol group). B: macroscopic currents of oocytes injected with either FL-Kv1.5 (8 fmol), FL-Kv1.5 + SAP97 (8:8 fmol) or FL-Kv1.5 + ZO-1 (8:8 fmol) cRNAs. The currents were recorded by a two-electrode voltage-clamp technique, with voltage steps from $-$ 60 mV to +60 mV in 10-mV increments. The holding potential was $-$ 70 mV. C: a summary of the current levels at 20 mV in each group. Data are shown as means ± SD. *P < 0.05. n = 5-6. D: relative maximal conductance (G/G_max) of the currents as a function of the membrane potential. The slope conductance was calculated assuming a reversal potential of $-$ 80 mV. No significant differences were found among the three groups (P > 0.05). Data were fitted by a Boltzmann function, with a slope factor and a half-conductance voltage of 11.6 and 0.8 mV in the Kv1.5 group, 11.4 and $-$ 2.0 mV in the SAP97 group, and 11.7 and $-$ 2.1 mV in the ZO-1 group (inset). Data are shown as means ± SD; n = 5-6.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

The targeting of ion channels to discrete plasma membrane domains of cardiac myocytes is critical to cardiac cell excitation.PDZ domain-containing proteins have been shown to play an importantrole in the targeting of sodium channels, NMDA receptors, andvoltage-gated potassium channels to discrete plasma membrane domainsin neuronal cells (8, 29, 30), but very little is knownabout the function of this family of proteins in the organizationof macromolecular signaling complexes in the heart. Recent studies(33) in cardiac myocytes revealed that the gap junction proteinconnexin43 associates with ZO-1 at the intercalated disks andthat the overexpression of dominant negative mutants of ZO-1 abolishesthe formation of recombinant gapjunctions.

In this study, we have demonstrated that SAP97, a PDZ domain-containing protein abundantly expressed in the heart, localizesto the intercalated disks and the lateral membranes of adult cardiacmyocytes. This plasma membrane distribution is identical to thatof Kv1.5, which suggests that Kv1.5 and SAP97 may interact incardiac tissue. However, we were unable to demonstrate this interactionin coimmunoprecipitation experiments from cardiac cell lysatesbecause of the low level of expression of Kv1.5 in the heart.Thus we used transient transfection experiments in COS-7 cellsto demonstrate the association of Kv1.5 with SAP97. Furthermore,we show that this interaction is specific, because a T-D-L toA-A-A mutation at the COOH-terminus of Kv1.5 abolished its associationwith SAP97. Although the tE-T-D-L COOH terminal sequence of Kv1.5differs from the tS/T-X-V consensus motif defined by Sheng andothers (17, 31), studies on the interaction of PSD-95 withthe COOH-terminus of Kir2.3 (tE-S-A-I) demonstrated that its PDZdomains do accommodate a leucine residue at the COOH-terminus(7). Moreover, SAP97/hDlg has been shown to associate withadenomotous Polyposis coli, human papillomavirus E6, and adenovirustype 9 E4, allowing the SAP97 COOH-terminal consensus bindingmotif to be extended to tX-S/T-X-V/I/L (19, 22, 25).

Although our cotransfection experiments in COS-7 cells clearly demonstrated the specific association of SAP97 and Kv1.5, theimmunocytochemical analysis of cotransfected COS-7 cells showedthat the majority of SAP97 and Kv1.5 polypeptides were localizedin the ER, with minimal accumulation on the cell membrane. Thisdistribution, which resembles that reported (32) for other Kv1channels in similar overexpression systems, differs from the plasmamembrane localization of endogenous SAP97 and Kv1.5 in cardiacmyocytes and probably reflects the inability of COS-7 cells totarget high levels of exogenously expressed proteins to theirproper intracellular destinations. Thus we used a different expressionsystem to investigate the functional consequences of the interactionof Kv1.5 and SAP97. As shown in Fig. 6, we demonstrated that thecoinjection of Kv1.5 with SAP97, but not with ZO-1, into Xenopusoocytes resulted in a significant increase of the steady-statelevels of Kv1.5-encoded currents. Recently, Burke et al. (6)showed that the interaction between PSD-95 and Kv1.4 in oocytesleads to the immobilization of Kv1.4 channels in the plasma membrane.Thus the channel clusters formed in the presence of PSD-95 werestable in size, shape, and position (6). We hypothesize thatthe enhancement of the whole cell Kv1.5-encoded currents in oocytesby SAP97 may occur by a similar mechanism, involving the recruitmentor retention of more functional channels (and/or channel-modulatingproteins) to the membranes, rather than increasing the channelopen probability or unitary conductance. Indeed, this model issupported by recent observations by Horio et al. (13), who showedthat the coexpression of SAP97 and the Kir channel in oocytesenhanced the Kir-encoded current without changing the single channelconductance or openprobability.

The level of expression and proper distribution of voltage-gated potassium channels are crucial for determining the shapeand duration of the action potential and the refractoriness ofcardiac myocytes (2, 9). PDZ domain-containing proteinshave emerged as an important group of scaffolding proteins thatinteract with ion channels, receptors, and their modulators (8,29). In this study, we have demonstrated that SAP97 interactswith Kv1.5 in heterologous expression systems and colocalizeswith it in cardiac myocytes. Further studies are needed to elucidatethe exact nature of these interactions and their functional significanceas related to outward potassium currents expressed in theheart.

	ACKNOWLEDGEMENTS

We thank Momoyo Murata and Ming-Ying Pu for excellent technical support. We also thank M. Wyszynski and M. Sheng for the generousgift of anti-SAP97 antibody and the rat SAP97 cDNA, S. Ryeom andD. A. Goodenough for the ZO-1 cDNA and the rat anti-ZO-1 antibody,M. Seki for pcDNA3 with a FLAG epitope, and Y. Kim for the MarathoncDNAlibrary.

	FOOTNOTES

^* P. D. Buckett and J. Zhou contributed equally to thiswork.

G. Koren is a recipient of National Heart, Lung, and Blood Institute Grant HL-46005 and an Established Investigator Awardfrom the American Heart Association. M. Murata is a recipientof a postdoctoral Fellowships Award from the Japan HeartFoundation.

Address for reprint requests and other correspondence: G. Koren, Cardiovascular Div., Brigham and Women's Hosp., 75 FrancisSt., Boston, MA 02115 (E-mail: koren{at}calvin.bwh.harvard.edu).

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.Section 1734 solely to indicate thisfact.

Received 25 May 2001; accepted in final form 8 August 2001.

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				A.-J. L.H.J. Aarnoudse, C. Newton-Cheh, P. I.W. de Bakker, S. M.J.M. Straus, J. A. Kors, A. Hofman, A. G. Uitterlinden, J. C.M. Witteman, and B. H.C. Stricker Common NOS1AP Variants Are Associated With a Prolonged QTc Interval in the Rotterdam Study Circulation, July 3, 2007; 116(1): 10 - 16. [Abstract] [Full Text] [PDF]

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