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The Journal of Neuroscience, December 1, 2000, 20(23):8736-8744
Localization and Enhanced Current Density of the Kv4.2 Potassium
Channel by Interaction with the Actin-Binding Protein Filamin
Kevin
Petrecca,
David M.
Miller, and
Alvin
Shrier
Department of Physiology, McGill University, Montréal,
Québec, Canada H3G 1Y6
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ABSTRACT |
Kv4.2 potassium channels play a critical role in postsynaptic
excitability. Immunocytochemical studies reveal a somatodendritic Kv4.2
expression pattern, with the channels concentrated mainly at dendritic
spines. The molecular mechanism that underlies the localization of
Kv4.2 to this subcellular region is unknown. We used the yeast
two-hybrid system to identify the Kv4.2-associated proteins that are
involved in channel localization. Here we demonstrate a direct
interaction between Kv4.2 and the actin-binding protein, filamin. We
show that Kv4.2 and filamin can be coimmunoprecipitated both in
vitro and in brain and that Kv4.2 and filamin share an overlapping expression pattern in the cerebellum and cultured hippocampal neurons. To examine the functional consequences of this
interaction, we expressed Kv4.2 in filamin+ and
filamin cells and performed immunocytochemical and
electrophysiological analyses. Our results indicate that Kv4.2
colocalizes with filamin at filopodial roots in
filamin+ cells but shows a nonspecific expression
pattern in filamin cells, with no localization to
filopodial roots. Furthermore, the magnitude of whole-cell Kv4.2
current density is ~2.7-fold larger in filamin+
cells as compared with these currents in filamin
cells. We propose that filamin may function as a scaffold protein in
the postsynaptic density, mediating a direct link between Kv4.2 and the
actin cytoskeleton, and that this interaction is essential for the
generation of appropriate Kv4.2 current densities.
Key words:
Kv4.2; potassium channels; filamin; postsynaptic density; subcellular localization; actin-binding protein
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INTRODUCTION |
Appropriate synaptic transmission is
dependent on the precise localization of ion channels and
neurotransmitter receptors at specific subcellular sites (Sheng, 1996 ;
Ziff, 1997; Colledge and Froehner, 1998; Craven and Bredt, 1998).
Voltage-gated K+ channels are expressed
within neurons in a variety of spatial distributions (Sheng et al.,
1992; Wang et al., 1994; Veh et al., 1995) where they function as
regulators of membrane excitability and synaptic transmission (Hille,
1991; Magee et al., 1998). Fast transient (A-type)
K+ channels, members of the voltage-gated
K+ channel family that are found in a wide
variety of excitable cells, have been implicated in the control of
action potential frequency and threshold, action potential
configuration, neurotransmitter release, and postsynaptic excitability
(Jan and Jan, 1997; Magee et al., 1998). Kv1.4 and Kv4.2, fast
transient K+ channel family members, are
segregated differentially in neurons. Kv1.4 is localized to
axons exhibiting a concentration at the presynaptic terminal (Sheng et
al., 1992; Zito et al., 1997; Arnold and Clapham, 1999), whereas Kv4.2
is localized to the somatodendritic compartment exhibiting a
concentration at the postsynaptic terminal (Sheng et al., 1992;
Maletic-Savatic et al., 1995; Alonso and Widmer, 1997).
In this study we set out to identify Kv4.2-associated proteins that are
involved in Kv4.2 localization. Here we report the identification and
characterization of a novel interaction between Kv4.2 and filamin, a
member of the  -actinin/spectrin/dystrophin family of actin-binding
proteins. Filamin originally was identified as a protein isolated from
motile alveolar macrophage that caused purified muscle actin to gel and
precipitate (Hartwig and Stossel, 1975). It is a widely distributed
member of a family of actin-binding proteins capable of cross-linking
actin filaments into orthogonal arrays and contributes substantially to
the formation and structure of the actin meshwork situated immediately
subjacent to the surface membrane (Marti et al., 1997).
Here we show that Kv4.2 and filamin can be coimmunoprecipitated from
both heterologous cells and brain extracts. Mapping studies reveal that
a four amino acid (aa) motif located ~30 aa upstream of the Kv4.2 C
terminus is required for Kv4.2-filamin interaction. We also show that
Kv4.2 and filamin share an overlapping expression pattern in the
cerebellum and cultured hippocampal neurons. Importantly, we
demonstrate that not only does filamin colocalize with Kv4.2 at
filopodial roots in heterologous cells, but it mediates Kv4.2 localization at these sites. Moreover, this interaction results in
2.7-fold increase in the magnitude of whole-cell Kv4.2 current density.
These findings demonstrate that filamin is a Kv4.2-interacting protein
that colocalizes with Kv4.2 in neurons and plays an important role in
the localization and functional surface membrane expression of Kv4.2 in
heterologous cells. We propose that filamin may function as a scaffold
protein in the postsynaptic density (PSD), mediating a direct link
between Kv4.2 and the actin cytoskeleton, and that this interaction is
essential for the generation of appropriate Kv4.2 current densities.
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MATERIALS AND METHODS |
Yeast two-hybrid screen and analysis of Kv4.2-filamin
interaction. Yeast two-hybrid screens were performed with the Y190
yeast strain harboring the reporter genes HIS3 and
 -galactosidase (-gal) under the control of upstream gal4-binding
sites (Clontech Laboratories, Palo Alto, CA). The Kv4.2C1 bait was
generated by incorporating unique NcoI and XbaI
restriction sites 5' and 3', respectively, via PCR and was fused to the
gal4 DNA-binding domain in vector pAS2-1. This bait, pAS2-1/Kv4.2C1,
was used to screen ~3 × 106 clones
from a human heart cDNA library constructed in the GAL4-activation domain vector pACT-2 (Clontech). Deletion variants of pAS2-1/Kv4.2C1 were constructed by PCR with the use of specific primers and were subcloned into pAS2-1 for yeast two-hybrid interactions. Mutations of
pAS2-1/Kv4.2C1 were generated by using QuikChange (Stratagene, La
Jolla, CA). The Kv4.3C bait was generated in a manner similar to
Kv4.2C1. The HERGC bait was generated by incorporating unique NcoI and BamHI restriction sites 5' and 3',
respectively, via PCR and was fused to the gal4 DNA-binding domain in
vector pAS2-1.
Expression constructs. The GST-Kv4.2(aa 471-630) fusion
construct was generated by digesting pAS2-1/Kv4.2C1 with
BamHI and SmaI (aa 471-630) and subcloning it
into pGEX-2T (Pharmacia, Piscataway, NJ). pCMV/myc-Kv4.2 was generated
by subcloning full-length Kv4.2 into pCMV-myc (Stratagene).
pSG-5/HA-filamin (filaminC, aa 2172-2705) was
generated by subcloning the original pACT-2 library clone, containing a
5' HA epitope, into pSG-5 (Stratagene). pCMV/myc-Kv4.2/600 was
constructed via PCR with the use of specific primers and was subcloned
into pCMV-myc. pCMV/myc-Kv4.2/ATAA mutations were generated with
QuikChange (Stratagene). pCMV/myc-HERG was generated by subcloning full-length HERG (generously provided by Dr. J. M. Nerbonne,
Washington University, St. Louis, MO) into pCMV-myc (Stratagene).
Transfection and immunocytochemistry in heterologous cells.
COS7, M2, and A7 cells were transfected with Lipofectamine (Life Technologies, Gaithersburg, MD) on
poly-D-lysine-coated coverslips (for immunocytochemistry)
or in 100 mm tissue culture dishes (for immunoprecipitation
experiments). Cells were fixed, permeabilized, and immunolabeled 42 hr
after transfection, as described (Petrecca et al., 1999). Rabbit
anti-HA (Babco, Richmond, CA) was diluted 1:500; mouse anti-myc (Santa
Cruz Biotechnology, Santa Cruz, CA) was used at a concentration of 2 µg/ml, and goat anti-filamin (Sigma, St. Louis, MO) was diluted 1:40.
Oregon green-conjugated goat anti-rabbit (Molecular Probes, Eugene,
OR), Cy3-conjugated goat anti-mouse (Jackson ImmunoResearch, West
Grove, PA), and FITC-conjugated donkey anti-goat secondary antibodies
were used at a dilution of 1:100. Immunofluorescence was visualized
with a Bio-Rad MicroRadiance confocal microscope (Hercules, CA) at an
optical thickness of ~7 µm. Digital images were prepared with Adobe
Photoshop (Mountainview, CA).
Coimmunoprecipitations. For immunoprecipitation, COS7,
filamin+, and
filamin cells that were plated on 100 mm
dishes were washed in ice-cold PBS, followed by solubilization
in 1 ml of ice-cold extraction buffer [(in mM) 50 Tris, pH
7.4, 150 NaCl, 1 EDTA plus 1% Nonidet P-40, 0.5% deoxycholate, and
0.1% SDS supplemented with 1 mM phenylmethylsulfonyl fluoride (PMSF) and 10 µg/ml each of pepstatin, aprotinin, and leupeptin]. The extraction was allowed to proceed with shaking for 3 hr at 4°C. Insoluble material was pelleted by centrifugation at
60,000 × g for 30 min, and the supernatants were used
for coimmunoprecipitation. Rabbit anti-HA (1:200) or rabbit anti-Kv4.2
(1:50) antibodies were added to the 100 µl of detergent extract,
which was incubated with inversion for 2 hr at 4°C. Equilibrated
protein A-Sepharose beads (Pharmacia) were added for a further 2 hr
with inversion and then were pelleted by centrifugation. Eluted
proteins were resolved by SDS-PAGE, transferred to a polyvinylidene
difluoride (PVDF) membrane, and visualized by immunoblotting with mouse
anti-myc (1 µg/ml), mouse anti-HA (1:500), or mouse anti-filamin
(1:500) antibodies, followed by horseradish peroxidase-conjugated goat anti-mouse antibody (1:5000; Jackson ImmunoResearch). Enhanced chemiluminescence was performed by using the
ECL+ detection kit (Amersham, Arlington
Heights, IL). Cerebellar membrane preparations and solubilization were
performed according to Luo et al. (1997). Briefly, adult rat cerebellum
from Sprague Dawley rats was homogenized in ice-cold 10 mM Tris-HCl, pH 7.4, containing 320 mM sucrose, 1 mM PMSF, and
10 µg/ml each of pepstatin, aprotinin, and leupeptin. The tissue
homogenate was centrifuged at 700 × g for 10 min at
4°C. The pellet was rehomogenized and centrifuged at 700 × g; the supernatants were combined and centrifuged at 37,000 × g for 40 min at 4°C. This pellet (P2) was
resuspended in 10 mM Tris-HCl, pH 7.4, supplemented with protease inhibitors. Protein concentrations were
determined via the Bradford assay. Then the protein (400 µg) was
solubilized by the addition of 0.1 vol of 10% sodium deoxycholate in
500 mM Tris-HCl, pH 9.0, and incubated for 30 min
at 36°C. A 0.10 vol of 1% Triton X-100/50 mM
Tris-HCl, pH 9.0, was added, and the preparation was dialyzed overnight
at 4°C, followed by centrifugation for 10 min at 100,000 × g. The supernatant was used for coimmunoprecipitation.
Anti-filamin antibodies (1:50, Sigma; 1:20, Serotec, Oxford, UK) were
added to the clarified supernatant of the solubilized P2 fraction and were mixed by inversion for 2 hr at 4°C. Equilibrated protein A-Sepharose beads were added and mixed by inversion for a further 2 hr
at 4°C. Eluted proteins were resolved by SDS-PAGE, transferred to a
PVDF membrane, and visualized by immunoblotting with an anti-Kv4.2 antibody generated against Kv4.2 residues 29-38: APPRQERKRT (1:400; Barry et al., 1995) or an anti-HERG antibody generated against HERG
residues 1145-1159: LTSQPLHRHGSDPGS (1:500; Pond et al., 2000),
followed by horseradish peroxidase-conjugated secondary antibody
(1:5000; Jackson ImmunoResearch). Enhanced chemiluminescence was
performed with the ECL+ detection kit
(Amersham). For antibody controls the immunoprecipitations were
performed by using control IgG, and the Kv4.2 antibody was blocked by
preincubating with the immunogenic peptide (100 µg/ml).
Filter overlay assays. GST and GST-Kv4.2 (aa 471-630)
fusion proteins, prepared from bacterial lysates, were purified with glutathione-Sepharose beads (Pharmacia). GST and GST-Kv4.2 were released from the beads, and ~3 µg of each fusion protein was electrophoresed. The resolved proteins were transferred to a PVDF membrane, and the denatured filter-bound proteins were renatured according to Wyszynski and Sheng (1999). Briefly, membranes were incubated in buffer A [(in mM) 10 HEPES, 60 KCl, 1 EDTA,
and 1 2-mercaptoethanol] containing 6 M guanidine
hydrochloride for 10 min at 4°C. Incubations were repeated for 10 min
at 4°C, using decreasing concentrations of guanidine hydrochloride
(3, 1.5, 0.75, 0.38, 0.19, 0.1, and 0 M). pSG-5/filamin C
(aa 2172-2705) was in vitro-translated (Promega, Madison,
WI) in the presence of [35S] and used
for the binding assay. The membrane was incubated with 10 µl of
[35S]filamin overnight at 4°C. The
next day the membrane was brought to room temperature, washed, and
submitted to autoradiography.
Myc-Kv4.2, myc-Kv4.2/600, and myc-Kv4.2/ATAA were in
vitro-translated in the presence of
[35S], electrophoresed, transferred, and
renatured as above. pSG-5/HA-filamin C (aa 2172-2705) was in
vitro-translated in the absence of
[35S] and used for the binding assay as
above. The next day the membrane was brought to room temperature,
washed, immunoblotted with anti-HA; enhanced chemiluminescence was
performed with the ECL+ detection kit
(Amersham). Then the membrane was stripped and submitted to autoradiography.
Neuron culture and immunocytochemistry. Low-density
hippocampal neuronal cultures were prepared from hippocampi dissected from 3-d-old Sprague Dawley rats and stored in an oxygenated solution. Then the hippocampi were exposed to an oxygenated papain solution for
~1 hr, dissociated, spun through BSA, resuspended in growth medium
[Neurobasal medium supplemented with B-27 (Life Technologies)], and
plated on modified 35 mm culture dishes coated with
poly-D-lysine and laminin. After 15 d in culture the
neurons were fixed in methanol for 15 min at  20°C, blocked in 0.5%
BSA for 30 min at room temperature, and immunolabeled as described
above with rabbit and Kv4.2 (1:100) and mouse and filamin (1:100).
Synaptophysin SVP38 monoclonal (Sigma) was used at a dilution of 1:500.
Immunofluorescence was visualized with a Bio-Rad MicroRadiance confocal
microscope at an optical thickness of ~7 µm.
Fresh-frozen adult rat cerebellum was cryosectioned at a thickness of
20 µm and thaw-mounted on Probe-On Plus slides (Fisher Scientific,
Pittsburgh, PA). Sections were air-dried at room temperature for 1 hr,
permeabilized, and blocked in 0.2% Triton X-100/0.5% BSA in PBS for
30 min. Sections were incubated with primary antibodies for 1 hr and
rinsed in PBS, followed by incubation with secondary antibodies for 1 hr. Antibodies were used at the following dilutions: Kv4.2, 1:100;
filamin (Sigma), 1:200; synaptophysin, 1:500. Immunofluorescence was
visualized with a Bio-Rad MicroRadiance confocal microscope at an
optical thickness of ~4 µm. Digital images were prepared with Adobe Photoshop.
Electrophysiological analysis. Patch-clamp technique,
performed with an Axopatch-1D amplifier (Axon Instruments, Foster City, CA), was used to measure whole-cell currents. Patch-clamp electrodes were filled with medium containing (in mM): 130 KCl, 1 MgCl2, 5 EGTA, 5 Mg-ATP, and 10 HEPES, pH 7.2. The pipette resistances were 3-4 M . The external medium contained
(in mM): 137 NaCl, 4 KCl, 1.8 CaCl2,
1 MgCl2, 10 glucose, and 10 HEPES, pH 7.4. Voltage-clamp pulses were delivered with custom-designed software
(Alembic Software, Montréal, Québec) implemented on a
personal computer equipped with an analog-to-digital board (Omega,
Stanford, CT). Data were sampled at 10 kHz and filtered at 2 kHz for
storage on computer hard disk and were analyzed with the same software.
Raw data are shown without leak correction. All experiments were
performed at room temperature (20-22°C). Activation of Kv4.2 current
was induced from a holding potential of 80 mV by 500 msec
depolarizing pulses to potentials between 70 and 70 mV in 10 mV steps
that were imposed at intervals of 10 sec. In some experiments the
holding potential was shifted to 20 mV to inactivate Kv4.2 channels, and the depolarizing protocol was repeated with steps ranging from 10
to 70 mV. Cell capacitance was estimated by fitting the current induced
by a small (10 mV) hyperpolarizing step and was verified by analog
measurement with the patch-clamp amplifier.
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RESULTS |
Interaction of Kv4.2 with filamin
In an effort to search for molecules that may be involved in the
localization of Kv4.2, we used the entire C terminus of Kv4.2 as bait
to screen a human heart cDNA library, using the yeast two-hybrid
system. The screen yielded multiple copies of four distinct cDNAs
encoding polypeptides that interacted specifically with the C terminus
of Kv4.2. No other clones were isolated in this screen. Furthermore, an
unrelated bait encoding the C terminus of HERG did not interact with
any of the isolated clones. Sequence analysis revealed that one of the
cDNAs was derived from filamin A, whereas the other three cDNAs were
derived from distinct but overlapping sequences of a highly homologous
polypeptide, filamin C (Fig.
1A).
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Figure 1.
The domain structure of filamin and interaction
with Kv4.2. A, Human cDNA clones isolated with a yeast
two-hybrid screen, using the Kv4.2 C-terminal region (aa 395-630) as
bait, are shown aligned below a schematic representation of the filamin
domain structure. ABD, Actin binding domain;
1-15, 16-23, and 24
represent ~96 aa repeats, each separated by hinge regions. Partial
cDNAs from filaminA and filaminC genes
were isolated. The numbers in parentheses
indicate the number of times each clone was isolated with the yeast
two-hybrid screen. B, Sequence requirements in the Kv4.2
C-terminal region for interaction with filamin. FilaminC
(aa 2172-2705), binding to Kv4.2C1 (aa 395-630), and deletion
derivatives were assayed by HIS3/-gal induction in
the yeast two-hybrid system. Residues 601-604 are required for
interaction with filamin; deletion and/or mutation of this region
abolishes the interaction. Kv4.3, which contains the identical binding
region, also interacts with filamin. The HERG C-terminal region (aa
864-1165) does bind filamin. The various bait fragments were tested
for filamin binding by semiquantitative yeast two-hybrid interaction
assays that were based on the degree of induction by the reporter genes
HIS3 and -gal. HIS3 activity was
measured by the percentage of colonies growing on histidine-lacking
medium as compared with the full-length Kv4.2 bait
(Kv4.2C1): +++, >75%; ++, >50%; +, >25%. -Gal
activity was determined from the time that was taken for the colonies
to turn blue in X-gal filter lift assays performed at room temperature:
+++, <2 hr; ++, <3 hr; +, <4 hr; , no significant activity.
H6, Sixth transmembrane domain.
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Three filamin isoforms (A, B, and C) have been identified, exhibiting
an overall amino acid homology of 70-72%. Each isoform shares three
common functional domains: a N-terminal actin-binding domain that is
structurally similar to that of the -actinin/spectrin/dystrophin family of cytoskeletal proteins, a semiflexible rod domain composed of
24 repeats interrupted by two short sequence inserts of 20-40 aa
between repeats 15-16 and 23-24, and a C-terminal self-association domain (Xie et al., 1998). All partial filamin cDNA fragments that were
isolated in this screen began at variable starting points within repeat
20 and were complete to the C terminus (Fig. 1A).
To define the site of interaction between Kv4.2 and filamin, we began
by examining successively larger C-terminal deletions of Kv4.2 that
bind filamin, using yeast two-hybrid analysis. Deletion of the
C-terminal 25 aa did not affect binding (Fig. 1B).
However, deletion of the next four amino acids (601-604) completely
abolished the interaction, suggesting that these amino acids (PTPP) are necessary for Kv4.2 interaction with filamin. We next generated point
mutations within this region, using the entire C-terminal Kv4.2 bait
fragment (Kv4.2C1). Substitution of the prolines in the 601-604 aa
region to alanines (PTPP ATAA) completely abolished the interaction
(Fig. 1B). These observations indicate that this proline-rich region is a domain that is necessary for Kv4.2 interaction with filamin. This sequence was noted to be identical in Kv4.3, consistent with its representing a site of interaction with both members of the Kv4 family. The subsequent use of yeast two-hybrid analysis confirmed that filamin also interacts with Kv4.3 (Fig. 1B).
Association of Kv4.2 and filamin in situ and
in vitro
To investigate the interaction of Kv4.2 and filamin further, we
tested whether these proteins form a complex in transfected heterologous cells. COS7 cells, transfected either singly or doubly with HA epitope-tagged filamin (HA-filamin) and myc-tagged Kv4.2 (myc-Kv4.2), myc-Kv4.2/600, or myc-Kv4.2/ATAA, were solubilized and
immunoprecipitated with an anti-HA antibody. The immunoprecipitates were resolved by SDS-PAGE and immunoblotted with anti-HA and anti-myc antibodies. As shown in Figure
2A, HA-filamin was
able to coimmunoprecipitate myc-Kv4.2 (lane 4). In
contrast, HA-filamin was not able to coimmunoprecipitate myc-Kv4.2/600
(lane 5), a deletion construct in which the last 30 aa,
including the PTPP binding site, had been removed, nor myc-Kv4.2/ATAA
(lane 6), a construct in which the PTPP binding motif
had been substituted with ATAA, indicating the specificity of the
Kv4.2/filamin association. In cells singly transfected with HA-filamin
or myc-Kv4.2, no myc-Kv4.2 was detected in the immunoprecipitates
isolated with the anti-HA antibody (Fig. 2A, lanes 2 and 3, respectively). To demonstrate the
specificity of this interaction further, we cotransfected the
cells with HA-filamin and myc-HERG. Figure 2A shows
that HA-filamin was unable to coimmunoprecipitate myc-HERG (lane
7) although myc-HERG was detected readily in cell lysates
(lane 8). Reciprocal immunoprecipitations were performed with Kv4.2-transfected filamin+ and
filamin cells. Figure
2B shows that Kv4.2 was able to coimmunoprecipitate filamin from filamin+ cells, but not from
filamin cells.
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Figure 2.
Coimmunoprecipitation in heterologous cells and
direct binding of Kv4.2 and filamin. A, Extracts from
COS7 cells singly or doubly transfected with HA-filamin and myc Kv4.2,
myc-Kv4.2/600, myc-Kv4.2/ATAA, or myc-HERG were immunoprecipitated with
anti-HA antibodies. The immunoprecipitates were immunoblotted with
anti-myc (top panel) and anti-HA antibodies
(bottom panel). B, Extracts from
Kv4.2-transfected filamin+ and
filamin cells were immunoprecipitated with
anti-Kv4.2 antibodies and immunoblotted with anti-filamin (top
panel) and anti-Kv4.2 (bottom
panel) antibodies. C, Filter overlay
assay showing direct in vitro binding of
[35S]filamin to Kv4.2. Glutathione
S-transferase (GST) and GST-Kv4.2
(aa 417-630) fusion proteins were prepared as crude bacterial lysates
and were purified with glutathione-Sepharose beads. Protein (5 µg)
was resolved by SDS-PAGE and transferred to a PVDF membrane. Top
panel, Renatured membrane overlaid with
[35S]filamin showing specific binding to
GST-Kv4.2. Bottom panel, Ponceau S-stained membrane
showing the position and similar abundance of proteins in each lane.
D, Filter overlay assay showing direct in
vitro binding of HA-filamin to in
vitro-translated Kv4.2, but not to Kv4.2/600 nor Kv4.2/ATAA. In
all, 15 µl of in vitro-translated
[35S]Kv4.2, [35S] Kv4.2/600,
and [35S]Kv4.2/ATAA was resolved by SDS-PAGE and
transferred to a PVDF membrane. Top panel, Renatured
membrane overlaid with in vitro-translated HA-filamin
and immunoblotted with anti-HA showing specific binding to Kv4.2, but
not to Kv4.2/600 nor Kv4.2/ATAA. Bottom panel, The
identical blot was stripped and exposed to autoradiography, showing the
position and similar abundance of the in
vitro-translated protein products in each lane.
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Direct interaction of Kv4.2 and filamin was tested in a filter overlay
assay that used a GST-Kv4.2 bacterial fusion protein and in
vitro-translated [35S]filamin (Fig.
2C). A purified GST-Kv4.2 (aa 471-630) fusion protein and
GST alone were separated by SDS-PAGE and transferred to a PVDF
membrane. The proteins were renatured on the membrane and probed with
in vitro-translated
[35S]filamin. Filamin bound to the
GST-Kv4.2 fusion protein but did not bind GST alone (Fig.
2C, top panel). Moreover, when the overlay assay was performed on non-renatured membranes, the interaction was
abolished, indicating that Kv4.2 must be in a native conformation for
association with filamin. To demonstrate the specificity of this
interaction further, we separated in vitro-translated
[35S]Kv4.2,
[35S]Kv4.2/600, and
[35S]Kv4.2/ATAA by SDS-PAGE and
transferred them to a PVDF membrane. The proteins were renatured on the
membrane and probed with in vitro-translated HA-filamin.
Figure 2D (top panel) shows that, on immunoblotting with an anti-HA antibody, filamin specifically interacts with Kv4.2 (lane 1, top panel),
but not Kv4.2/600 (lane 2, top panel) nor
Kv4.2/ATAA (lane 3, top panel). Taken
together, these data show that Kv4.2 and filamin form a complex in
heterologous cells and that they interact directly in an in
vitro assay.
Association of Kv4.2 and filamin in vivo
To determine whether Kv4.2 and filamin interact in
vivo, we performed coimmunoprecipitation experiments from rat
cerebellum. Membrane fractions from rat cerebellar homogenates were
solubilized, and the supernatant was immunoprecipitated with two
distinct anti-filamin antibodies. The immunoprecipitates were resolved
by SDS-PAGE, transferred to a PVDF membrane, and immunoblotted with an
anti-Kv4.2 antibody (Fig. 3A).
A band at ~74 kDa is seen with anti-Kv4.2 immunoblotting, indicating
that filamin is able to coimmunoprecipitate Kv4.2 (Fig. 3A,
lanes 1, 2). Kv4.2 was not precipitated when control IgG was
used as the precipitating antibody (lane 5), indicating the
specificity of the coimmunoprecipitation. Moreover, competition of the
anti-Kv4.2 antibody with the immunogenic peptide completely blocked the
labeling of Kv4.2 band (lane 4). As a further control demonstrating the specificity of this interaction, we determined whether filamin was also capable of immunoprecipitating HERG. Figure
3B shows that, although HERG was readily detectable in brain
lysates (Fig. 3B, lane 1), no HERG could be
immunoprecipitated with either anti-filamin antibody (Fig.
3B, lanes 2, 3). These data demonstrate that
Kv4.2 and filamin form a complex in brain.
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Figure 3.
Biochemical association of Kv4.2 and filamin in
rat brain. Shown is the coimmunoprecipitation of Kv4.2 and filamin from
cerebellum. Membrane fractions of cerebellar homogenate were
solubilized and immunoprecipitated as indicated. A, The
immunoblot shows that two different anti-filamin antibodies
(lane 1, Sigma; lane 2, Serotec)
specifically precipitate Kv4.2, as visualized by blotting with an
anti-Kv4.2 antibody. Immunoprecipitation with control IgG (lane
5) does not pull down Kv4.2, demonstrating the specificity of
the immunoprecipitation and competition of the anti-Kv4.2 antibody; the
immunogenic peptide completely blocked the labeling of Kv4.2
(lane 4). The Input lane was
loaded with 5% of the extract used for immunoprecipitation
(lane 3). B, The immunoblot shows that
two different anti-filamin antibodies (lane 2, Sigma;
lane 3, Serotec) do not pull down HERG, as visualized by
blotting with an anti-HERG antibody. The Input lane was
loaded with 5% of the extract that was used for immunoprecipitation
(lane 1).
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Kv4.2 colocalizes with filamin in cultured hippocampal neurons
The results described above show that Kv4.2 and filamin interact
both in vitro and in brain. Do filamin and Kv4.2 colocalize in neurons? This question was addressed by determining the localization of endogenous Kv4.2 and filamin in cultured hippocampal neurons. As
shown in Figure 4, A-D, Kv4.2
exhibits a punctate staining pattern along dendrites, matching closely
that of the presynaptic marker synaptophysin. Colabeling of endogenous
Kv4.2 and endogenous filamin shows that filamin colocalizes with Kv4.2
in dendrites with an enrichment at synapses (Fig.
4E,F). Thus, at the light microscope level,
filamin colocalizes with Kv4.2 in dendrites.
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Figure 4.
Colocalization of Kv4.2 and filamin in cultured
hippocampal neurons. Cultured hippocampal neurons were
double-immunolabeled by using anti-Kv4.2 (A, C, E),
anti-synaptophysin (B, D), and anti-filamin
(F) antibodies. A-D, Double
immunolabeling of endogenous Kv4.2 and synaptophysin shows that Kv4.2
is distributed in a punctate pattern along dendrites, matching closely
with that of synaptophysin. E, F, Double immunolabeling
of endogenous Kv4.2 and filamin shows that Kv4.2 and filamin colocalize
in a punctate pattern along the dendrites. Large
insets in E and F represent high
magnification view of small insets in each
panel, respectively.
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Kv4.2 and filamin colocalize in cerebellum
Kv4.2 immunoreactivity is present at high levels in the granule
cell layer of the cerebellar cortex, exhibiting a somatodendritic localization (Sheng et al., 1992). As such, we used high-resolution confocal imaging to determine whether Kv4.2 and filamin colocalize in
cerebellar sections, using a previously characterized anti-Kv4.2 antibody (Barry et al., 1995). Figure
5A shows that Kv4.2 is
expressed abundantly in the cerebellar granule cell layer, consistent
with Sheng et al. (1992), and that there is an overlap between Kv4.2 and filamin immunoreactivity in this cell layer. To determine whether
this colocalization represents a synaptic localization, we determined
whether Kv4.2 immunoreactivity correlated with that of the synaptic
marker synaptophysin. Figure 5B shows that the Kv4.2
expression pattern highly correlates with that of synaptophysin. Thus,
at the light microscope level, these data show that Kv4.2 and filamin
share an overlapping expression pattern in the granule cell layer of
the cerebellum, consistent with the direct association of these
proteins in vivo.
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Figure 5.
Colocalization of Kv4.2 and filamin in cerebellum.
Fresh-frozen 20-µm-thick cryosections of adult rat cerebellum were
double-immunolabeled with anti-Kv4.2 (Cy3) and anti-filamin (Oregon
green) antibodies (A) and anti-Kv4.2 (Cy3) and
anti-synaptophysin (Oregon green) antibodies (B).
A, Low-magnification (left) and
high-magnification (right) images show that Kv4.2 and
filamin colocalize in the cerebellar granule cell layer.
B, Low- and high-magnification images
(inset in top left panel indicates the
region from which high-magnification images were obtained) show that
the Kv4.2 and synaptophysin distribution patterns overlap.
G, Granule cell layer; M, molecular
layer; W, white matter. Scale bars: A, 50 µm; B, 100 µm.
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Filamin localizes Kv4.2 to filopodial roots in
heterologous cells
To examine whether filamin colocalizes with Kv4.2 in heterologous
cells and to determine the significance of this interaction on Kv4.2
localization, we transfected myc-Kv4.2 into a filamin-deficient human
malignant melanoma cell line (M2) and a M2 cell line stably expressing
filamin (Cunningham et al., 1992) and analyzed their localization
immunocytochemically. Figure 6,
A and B, shows that myc-Kv4.2 accumulates and
colocalizes with filamin in filamin+ M2
cells at the roots of filopods. Filamin localization at the roots of
filopods is consistent with a previous report demonstrating the role of
filamin in the induction of filopodia (Ohta et al., 1999). In contrast,
Kv4.2 expression in filamin M2 cells
shows a more uniform expression pattern, with no localization at
filopodial roots (Fig. 6G,H). To determine whether
the loss of Kv4.2 localization at filopodial roots is directly
attributable to the absence of the filamin interaction or to a general
loss of filamin expression, we transfected nonfilamin-interacting
myc-Kv4.2/600 and myc-Kv4.2/ATAA mutant channels into
filamin+ M2 cells. Similar to wild-type
Kv4.2 distribution in filamin M2 cells,
neither myc-Kv4.2/600 nor myc-Kv4.2/ATAA colocalizes with filamin in
filamin+ M2 cells, but each shows a more
uniform expression pattern with no specific localization (Fig.
6C-F). These data demonstrate that Kv4.2 colocalizes
with filamin in heterologous cells and that the accumulation of Kv4.2
at filamin-rich filopodial roots is dependent on its interaction with
filamin.
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Figure 6.
Colocalization and accumulation of Kv4.2 and
filamin at filopodial roots in filamin+ heterologous
cells. Filamin+ M2 cells were transfected with
myc-Kv4.2 (A, B), myc-Kv4.2/600 (C, D),
and myc-Kv4.2/ATAA (E, F).
Filamin M2 cells were transfected with myc-Kv4.2
(G, H). Cells were double-immunolabeled with
anti-myc (A, C, E, G) and anti-filamin (B, D, F,
H) antibodies. A, B, Kv4.2
exhibits a discrete subcellular distribution, colocalizing with filamin
at filopodial roots in filamin+ M2 cells. C,
D, Deletion of the C-terminal 30 aa of Kv4.2, including the
filamin-binding site (Kv4.2/600), and substitution of the prolines with
alanines within the filamin-binding site of Kv4.2 (Kv4.2/ATAA;
E, F) results in a loss of Kv4.2 colocalization
with filamin and a resulting nonspecific distribution with a marked
absence at filopodial roots in filamin+ M2 cells.
G, H, Kv4.2 exhibits a nonspecific distribution in
filamin M2 cells. Arrows indicate
Kv4.2 and filamin localization at filopodial roots.
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Effect of Kv4.2-filamin association on whole-cell Kv4.2
current density
To determine the significance of the Kv4.2-filamin association on
whole-cell Kv4.2 current, we recorded, using the patch-clamp technique,
the current generated from Kv4.2-transfected
filamin+ and
filamin cells in whole-cell clamp mode.
As is evident from the recordings, there is a prominent transient
outward current present in Kv4.2-transfected cells in the presence or
absence of filamin. However, the current density, measured from the
initial transient outward peak to the current level at the end of the
500 msec step, was 2.6-fold greater in the
filamin+ cells than in the
filamin cells (Fig.
7A,B). This also is reflected
in the bar graph (Fig. 7F). These results demonstrate
that Kv4.2 channels are expressed functionally and suggest that their
interaction with filamin enhances the current density. To determine
whether this difference in whole-cell current density was directly
attributable to the Kv4.2-filamin interaction or to a nonspecific lack
of filamin in filamin cells, we
expressed the Kv4.2/ATAA nonfilamin-interacting mutant channel in
filamin+ cells. As shown in Figure
7C, the magnitude of the whole-cell Kv4.2/ATAA current
density was 2.8-fold less than that of wild-type Kv4.2 expressed in
filamin+ cells and similar to that of
wild-type Kv4.2 expressed in filamin
cells. This is reflected in the bar graph (Fig. 7F).
It is noteworthy that the Kv4.2/ATAA currents had markedly slower
inactivation kinetics as compared with wild-type Kv4.2, most likely
resulting from a nonfilamin-related effect on C-type channel
inactivation. Experiments conducted with untransfected or
mock-transfected cells never expressed a transient outward current.
Instead, a small, relatively rapidly activating endogenous delayed
rectifier current generally was observed that did not inactivate during
the 500 msec step (see Fig. 6D,E). The same
endogenous current also could be revealed in cells expressing Kv4.2
current when the Kv4.2 channels were inactivated by changing the
holding potential from 80 to 20 mV. Last, Kv4.2 currents were
blocked reversibly by 10 mM 4-aminopyridine
(n = 8; data not shown).
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Figure 7.
Effect of the Kv4.2-filamin association on
whole-cell Kv4.2 current density. Large, transient whole-cell currents
were induced in filamin+ cells transfected with
Kv4.2 (A) by 500 msec depolarizing steps from a
80 mV holding potential to potentials between 70 and 70 mV in 10 mV
steps that were imposed at 10 sec intervals. Recordings from
filamin cells transfected with Kv4.2
(B) and filamin+ cells
transfected with Kv4.2/ATAA (C) revealed a
smaller transient outward current. In untransfected
filamin+ (D) or
filamin (E) cells this
transient current was not observed. Instead, a delayed rectifier-like
endogenous current was recorded. Similar endogenous currents were
revealed in filamin+ and
filamin cells transfected with Kv4.2 by imposing
the depolarizing step protocol from a 20 mV holding potential (data
not shown). The differences in the magnitude of the transient outward
current as measured from the initial transient outward peak to the
current level at the end of the 500 msec depolarizing steps to +30 mV
were found to be 2.6-fold greater in Kv4.2-transfected
filamin+ cells (n = 22) than in
filamin cells (n = 15;
*p < 0.001) and 2.8-fold greater in
Kv4.2-transfected filamin+ cells than in
Kv4.2/ATAA-transfected filamin+ cells
(n = 15; *p < 0.001). This
difference is reflected in the bar graph
(F).
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To determine whether the ~2.7-fold increase in whole-cell Kv4.2
current density is attributable to a higher density of channels in the
surface membrane or to a change in the single-channel conductance, we
assessed the single-channel conductance of Kv4.2 expressed in each of
these cell lines. In agreement with previous studies (Cooper and
Shrier, 1985; Cooper and Shrier, 1989), we found single-channel conductances with high K+ concentration in
the pipette medium to be 46.0 ± 1.79 pS (n = 5)
and 43.6 ± 1.33 pS (n = 5) in
filamin+ and
filamin cells, respectively (data not
shown). This difference was determined not to be statistically
significant. As a further control we transfected the HERG
K+ channel into
filamin+ (n = 4) and
filamin (n = 4) cells
and recorded the magnitude of the whole-cell current. Our results
revealed no difference in current density between these cell lines
(data not shown). Moreover, total cellular Kv4.2 protein expression is
equivalent in filamin+ and
filamin cells (see Fig.
2B, bottom panel). Taken together,
the electrophysiological data reveal that Kv4.2 is expressed in the
surface membrane in the presence or absence of the filamin interaction;
however, the presence of the interaction results in an increase in the
density of Kv4.2 channels that are expressed in the surface membrane.
| |
DISCUSSION |
Here we report a novel protein-protein interaction between Kv4.2
and filamin, a member of the -actinin/spectrin/dystrophin family of
actin-binding proteins. We have defined a PTPP motif in the C terminus
of Kv4.2 (aa 601-604) that is required for filamin interaction.
Deletion or mutation of this motif abolishes the interaction, as
determined by the yeast two-hybrid assay. We also show that Kv4.3,
which contains the identical C-terminal tail PTPP motif, also interacts
with filamin in the yeast two-hybrid assay. In addition, we demonstrate
that Kv4.2 and filamin directly interact in in vitro assays
and can be coimmunoprecipitated from heterologous cells and rat brain
extracts. Furthermore, immunolabeling experiments reveal that Kv4.2 and
filamin share an overlapping expression pattern in the cerebellum and
cultured hippocampal neurons.
Immunocytochemical analyses show that Kv4.2 is enriched and colocalizes
with filamin at cellular specializations: the roots of filopods in
filamin+ heterologous cells. Deletion or
mutation of the Kv4.2-binding motif abolishes this enrichment and
colocalization, indicating that filamin plays a role in Kv4.2
localization. Expression of Kv4.2 in
filamin cells also results in a loss of
Kv4.2 localization at filopodial roots. Moreover, the magnitude of
whole-cell Kv4.2 current density is ~2.7-fold larger in
filamin+ cells as compared with these
currents in filamin cells. The combined
immunocytochemical and electrophysiological data indicate that the
observed difference in the magnitude of whole-cell Kv4.2 current
density most likely is attributable to an increase in the number of
functional channels in the surface membrane as opposed to a change in
the single-channel conductance of Kv4.2. Taken together, these findings
indicate that filamin is a Kv4.2-interacting cytoskeletal protein that
colocalizes with Kv4.2 in neurons and plays an important role in the
localization and functional surface membrane of Kv4.2 in heterologous cells.
What determines filamin localization?
The data presented in this study and others indicate that filamin
exhibits a restricted distribution within the cell, localized primarily
at cellular specializations, e.g., focal adhesion sites (Burridge and
Chrzanowska-Wodnicka, 1996; Schwarzman et al., 1999) and filopodial
roots (Ohta et al., 1999). This restricted localization may be
attributable to its interaction with the adhesion molecule integrin, a
constituent protein of cellular specializations (Burridge and
Chrzanowska-Wodnicka, 1996). Interestingly, both integrin and filamin
have been implicated as molecular components of the neuromuscular
junction (NMJ), and 1-integrin has been shown to play a
physiological role in the agrin-mediated signaling cascade that leads
to AChR clustering (Meier and Wallace, 1998). Similarly, filamin has
been implicated in stabilizing AChR clustering at the NMJ (Shadiack and
Nitkin, 1991) and recently has been shown to interact directly with
sarcoglycan (Thompson et al., 2000).
Role of filamin at the synapse?
This study demonstrates that filamin colocalizes and interacts
with Kv4.2 in neurons. Using the yeast two-hybrid assay, we mapped the
filamin interaction site on Kv4.2 to a proline-rich region (PTPP) at aa
601-604. This PTPP motif constitutes a consensus SH3-binding module
(Pawson and Scott, 1997); however, no SH3 domains were found within
filamin. Alternatively, the dependence of binding on prolines suggests
a role for these amino acids in establishing the appropriate secondary
structure that is required for Kv4.2-filamin interaction. A similar
proposal has been made for the interaction between group 1 metabotropic
glutamate receptors and Homer proteins (Tu et al.,
1998).
The postsynaptic localization of Kv4.2 is consistent with the
involvement of this fast-transient K+
channel in regulating the excitability of the postsynaptic membrane and
thus the reception and integration of synaptic signals (Sheng et al.,
1992; Alonso and Widmer, 1997). The combined immunocytochemical and
electrophysiological findings presented here support two overlapping roles for filamin with respect to Kv4.2 binding: surface membrane expression and subcellular localization of Kv4.2.
In heterologous cells, filamin is necessary for the induction of
filopodia (Ohta et al., 1999). A model has been put forth in which
dendritic spine formation results from the induction of filopodial-like
dendritic spine precursors under synaptic boutons on axons (Matus,
1999). Filamin also has been demonstrated to exist in two intracellular
pools in a phosphorylation-dependent manner: one associated with the
plasma membrane and the other within the actin cytoskeletal network
(Sharma et al., 1995; Meyer et al., 1997; Ott et al., 1998). Thus,
signaling events at the PSD may regulate the extent of Kv4.2 expression
in the surface membrane via its interaction with filamin.
What is the importance of positioning this
K+ channel in such a restricted manner?
The answer may lie not within the ion channel but in the complex with
which it is associated. Modulatory enzymes precisely localized to the
subsynaptic membrane could provide a rapid activity-dependent mechanism
for the regulation of channel expression in the surface membrane and/or
channel kinetics, thus modulating postsynaptic excitability. In fact, a
role for PKC in Kv4.2 and filamin modulation has been established
(Nakamura et al., 1997; Glogauer et al., 1998). Interestingly, PKC has
been shown to bind -integrin (Ng et al., 1999), while the
interaction of -integrin with filamin has been clearly established
(Sharma et al., 1995; Loo et al., 1998; Pfaff et al., 1998). Thus, via its interaction with Kv4.2 and -integrin, filamin may serve as a
molecular scaffold to localize Kv4.2 to the postsynaptic membrane and/or to mediate the assembly of a macromolecular complex linking Kv4.2 to the actin cytoskeleton and signaling molecules. A similar signaling complex has been described within which Yotiao, a scaffold protein that directly links the NMDA receptor with type I protein phosphatase and cAMP-dependent protein kinase, facilitates the regulation of channel activity (Westpal et al., 1999).
The ability of filamin to localize Kv4.2 to cellular specializations
and stabilize its expression in the surface membrane in heterologous
cells identifies it as a candidate protein involved in Kv4.2
localization and surface membrane expression at the synapse. Further
characterization of the Kv4.2/filamin interaction in neurons will be
required to address the role of filamin in Kv4.2 localization at the
neuronal synapse.
| |
FOOTNOTES |
Received July 13, 2000; revised Aug. 28, 2000; accepted Sept. 15, 2000.
This work was supported by the Medical Research Council of Canada
(A.S.). K.P. was supported by a grant from the Fonds pour la Formation
de Chercheurs et l'Aide à la Recherche. We thank Damian G. Wheeler for preparing the cultured hippocampal neurons; Dr. P. A. Janmey (University of Pennsylvania, Philadelphia, PA) for supplying the
M2 and A7 cell lines; and Dr. J. M. Nerbonne (Washington
University, St. Louis, MO) for providing us with Kv4.2, Kv4.3, and HERG
cDNAs and the Kv4.2 and HERG antibodies. We are also grateful to Dr.
A. P. Haghighi for a critical reading of this manuscript.
Correspondence should be addressed to Dr. Alvin Shrier, Department of
Physiology, McGill University, 3655 Drummond Street, Montréal,
Québec, Canada H3G 1Y6. E-mail: ashrier{at}med.mcgill.ca.
| |
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