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The Journal of Neuroscience, April 1, 1998, 18(7):2360-2369
dSLo Interacting Protein 1, a Novel Protein That Interacts with
Large-Conductance Calcium-Activated Potassium Channels
Xiao-ming
Xia,
Birgit
Hirschberg,
Sarah
Smolik,
Michael
Forte, and
John P.
Adelman
Vollum Institute, Oregon Health Sciences University, Portland,
Oregon 97201
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ABSTRACT |
Large-conductance calcium-activated potassium channels (BK
channels) are activated by depolarized membrane potential and elevated levels of intracellular calcium. BK channel activity underlies the fast
afterhyperpolarization that follows an action potential and attenuates
neurotransmitter and hormone secretion. Using a modified two-hybrid
approach, the interaction trap, we have identified a novel protein from
Drosophila, dSLIP1 (dSLo interacting protein), which
specifically interacts with Drosophila and human BK
channels and has partial homology to the PDZ domain of  1 syntrophin.
The dSLIP1 and dSlo mRNAs are expressed coincidently throughout the Drosophila nervous system, the two proteins interact
in vitro, and they may be coimmunoprecipitated from
transfected cells. Coexpression of dSLIP1 with dSlo or hSlo BK channels
in Xenopus oocytes results in reduced currents as
compared with expression of BK channels alone; current amplitudes may
be rescued by coexpression with the channel domain that interacts with
dSLIP1. Single-channel recordings and immunostaining of transfected
tissue culture cells suggest that dSLIP1 selectively reduces Slo BK
currents by reducing the number of BK channels in the plasma
membrane.
Key words:
BK channels; two-hybrid; interacting protein; chaperone
protein; regulated expression; current density
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INTRODUCTION |
Neuronal action potentials are
followed by an afterhyperpolarization (AHP) that has several kinetic
components and may have profound consequences for the firing pattern of
the neuron. During an action potential the concerted influences of
increased intracellular calcium and depolarized membrane potential
activate two classes of calcium-activated potassium channels:
large-conductance calcium- and voltage-dependent channels (BK channels)
and small-conductance (SK) channels activated only by calcium.
Together, these distinct classes of calcium-activated potassium
channels are responsible for the different kinetic components of the
AHP. Application of BK channel blockers such as charybdotoxin (CTX) or
tetraethylammonium (TEA) has shown that BK channels contribute to
action potential repolarization and underlie the fast component of the
AHP (fAHP), which develops rapidly (rise time 1-2 msec) and decays
within tens of milliseconds (Lancaster and Nicoll, 1987 ; Storm, 1987), whereas the subsequent slow components (sAHP) are attributable to SK
channels and underlie spike frequency adaptation (Hotson and Prince,
1980; Madison and Nicoll, 1984; Yarom et al., 1985).
Regulation of BK channel activity exerts a powerful modulation on
neuronal excitability. Electrophysiological studies have shown that
native BK channels are regulated by a wide range of second messengers,
including several protein kinases and protein phosphatases (Ewald et
al., 1985; Chung et al., 1991; Reinhart et al., 1991) and G-proteins
(Cole and Sanders, 1989; Toro et al., 1990; Scornik et al., 1992). In
addition, mammalian BK channels have a closely associated  -subunit
that modifies the calcium sensitivity of the channel and that itself
may be the target for regulatory second messengers (McManus et al.,
1995; Dworetzky et al., 1996; Hanner et al., 1997).
Other mechanisms may influence the fAHP via indirect effects on BK
channels. There is evidence that, at least in some neuronal cell types,
BK and voltage-dependent calcium channels (VDCCs) are associated
closely and may be coupled physically (Gola and Crest, 1993; Robitaille
et al., 1993; Issa and Hudspeth, 1994). Other post-translational
modulatory effects on BK channels have been described, but the
underlying molecular mechanisms have not yet been established
(Subramony et al., 1996; Subramony and Dryer, 1997). For other
voltage-gated potassium channels, a distinct -subunit, Kv2,
associates with the -subunits early in channel biosynthesis and
exerts dramatic, chaperone-like effects on the -subunits, including
stabilization and increased cell surface expression (Rettig et al.,
1994; Shi et al., 1996). These results suggest that the subcellular
distribution and density of BK channels will affect the kinetics of the
fAHP and neuronal excitability.
Both classes of calcium-activated potassium channels now have been
cloned. Heterologous expression studies have demonstrated that the
cloned channels faithfully reproduce the biophysical characteristics of
their native counterparts (Atkinson et al., 1991; Adelman et al., 1992;
Butler, 1993; Köhler et al., 1996). To identify other proteins,
such as -subunits, that interact with BK channels and influence BK
expression, we used the C-terminal domain of a cloned BK channel in a
two-hybrid screen. One of the clones identified as interacting with the
dSlo BK channel, dSLIP1 (dSLo interacting protein), appears to regulate
the number of BK channels in the plasma membrane.
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MATERIALS AND METHODS |
Interaction trap. A detailed description of the
interaction trap has been presented previously (Gyuris et al., 1993).
Briefly, the C-terminal 499 residues of dSlo (dSlo-C665-1164) were
fused to the C-terminal oligomerization region of LexA in the parent plasmid pEG202, which has HIS3 as a selectable marker and a 2 µm
replicator. In this plasmid the LexA-dSlo-C665-1164 fusion (the
"bait") is expressed constitutively from the yeast ADH
promoter/terminator. The bait plasmid was transformed into the yeast
strain EGY195, auxotrophic for histidine (his3), tryptophan
(trp1), uracil (ura3-52), and leucine
(leu2). For selection of interacting proteins, EGY195 contains an integrated copy of the leu2 gene in which the
upstream regulatory sequences have been replaced by two LexA operators. EGY195 also carries pSH18-34, which contains an expression cassette for -galactosidase driven by the Gal1 promoter under the control of
four LexA operators, as well as the URA3 selectable marker. The
presence of this plasmid allows an independent verification of
LexA-driven transcriptional activation. EGY195 containing the bait
plasmid and the -galactosidase reporter plasmid was transformed with
a cDNA library constructed in pJG4-5. Expression of the cDNA is under
the control of the Gal1 promoter, and the expressed protein is a fusion
with (N- to C-) a nuclear localization signal, the B42 transcriptional
activation domain (Ma and Ptashne, 1988), the HA1 epitope tag, the
cDNA, and the ADH transcriptional terminator. pJG4-5 also carries a
TRP1+ selectable marker and a 2 µm replicator.
Thus, a cell that has been transformed with a cDNA plasmid encoding a
protein that interacts with the bait will activate transcription of
leu2 and -galactosidase independently via LexA-LexA
operator interactions, when grown on galactose as the carbon source;
selection is for his, trp, ura, and leu prototrophy, and colonies are
blue in a -galactosidase filter assay.
Yeast containing the bait plasmid and the -galactosidase reporter
plasmid were transformed with a Drosophila embryo cDNA library (generous gift of Dr. Russ Finley, Harvard University, Cambridge, MA) according to a variation of the procedure of Schiestl and Gietz (1989). The transformation mix was plated to galactose Ura , Trp,
His, and Leu plates;
transformation complexity (~1.5 × 106) was
determined by plating an aliquot to this medium containing leucine.
After 4 d, ~760 LEU+ colonies appeared. These
were patched to glucose Ura,
Trp, and His plates and
scored on galactose Ura, Trp,
His, and Leu plates and a
-galactosidase filter assay, yielding eight clones that grew
strongly in the absence of leucine and that also were deep blue on
X-gal. These plasmids were rescued by transforming yeast miniprep DNA
into Escherichia coli KC8, a trp
strain, permitting specific rescue of the trp+ prey
plasmid. Miniprep DNAs from individual E. coli transformants were retested individually by transforming them back into EGY195 carrying the bait and -galactosidase reporter plasmids, as well as
into EGY195 carrying only the reporter plasmid. One of the clones was
able to induce leucine prototrophy in the absence of the bait plasmid
and was eliminated from further analysis. The nucleotide sequences for
the other seven clones were determined; three clones, one an RNA
binding protein, one a mitochondrial enzyme, and one a transcription
factor, were not studied further. The remaining four clones were
examined for overlapping expression patterns with dSlo by using
in situ hybridization; one clone, dSLIP1, was chosen for
further study. EGY195 and pSH18-34 were the generous gifts of Drs.
Erica Golemis and Roger Brent (Harvard University, Cambridge, MA). To
isolate dSLIP1 5' coding sequences, we performed 5' rapid amplification
of cDNA ends (RACE) reactions, as previously described (Bond et al.,
1994). Nucleotide sequences were determined by Sequenase (United States
Biochemical, Cleveland, OH); nucleic acid and protein sequence analyses
were performed by using the Genetics Computer Group suite of software
(Madison, WI).
Antibodies. Fragments of dSlo (C665-1164 and full-length
dSLIP1) were cloned into the polyHis fusion vector pET16 and
transformed into E. coli strain BL21(DE3). Fusion proteins
were induced by treating the cultures with isopropyl thiogalactoside
(IPTG). After induction, bacteria were pelleted and then lysed with
lysozyme and sonication. Inclusion bodies were pelleted, washed once
with PBS, repelleted, and resuspended in PBS. Inclusion bodies were used to immunize rabbits (Biodesign International, Kennebunkport, ME),
and bleeds were assessed individually by probing Western blots of
appropriate glutathione S-transferase (GST) fusion
proteins.
Western blot. For Western blots, Drosophila
larvae (~1 gm; 0-24 hr) were homogenized thoroughly and sonicated in
500 µl of 2× SDS-PAGE loading buffer and pelleted in a table-top
centrifuge; 15 µl of the supernatant was subjected to 10% SDS-PAGE.
After electrophoresis, proteins were electroblotted to a nitrocellulose filter. The blot was preabsorbed with 2.5% dry milk in PBS and 0.1%
Triton X-100 and probed at room temperature for 2 hr with a 1:5000
dilution of either dSlo or dSLIP1 antiserum (0.5% dry milk in PBS and
0.1% Triton X-100). Then the blot was washed three to five times with
PBS and 0.1% Triton X-100, incubated at room temperature for 1 hr with
secondary antibody (1:5000 dilution of HRP-conjugated anti-rabbit
antibody; Santa Cruz Biotechnology, Santa Cruz, CA), and washed three
to five times with PBS and 0.1% Triton X-100. ECL detection reagent
(Amersham, Arlington Heights, IL) was added and incubated for 1 min
before exposure to x-ray film for 30 min. Finally, the image was
scanned by an ARCUS II AGFA scanner (AGFA, Mortel, Belgium).
In situ hybridization to polytene chromosomes and embryo
sections. Genome mapping by in situ hybridization to
polytene chromosomes was done as described (Quan et al., 1993).
Digoxigenin-11-UTP-labeled riboprobes for in situ
hybridization to embryos were generated from dSLIP1 and dSlo cDNA
clones by in vitro transcription. Subsequent processing of
embryos was done as described (O'Neil and Bier, 1994).
Northern blot analysis. Drosophila embryos (~1
gm; 0-24 hr) were homogenized with a Dounce homogenizer, and
poly(A+) mRNA was oligo-dT-selected; 3 µg was
prepared as a Northern blot and probed with radiolabeled full-length
dSLIP1 antisense RNA (50% formamide, 5% SDS, 400 mM
NaPO4, pH 7.2, and 1 mM EDTA at 65°C
overnight and then washed in 1% SDS and 0.5× SSC at 50°C). The blot
was exposed to x-ray film for 18 hr and scanned as described above.
GST pull-down experiments. The indicated fragments of either
dSlo or dSLIP1 were fused to GST in pGEX-KG (Pharmacia, Piscataway, NJ)
and expressed in E. coli DH5 or were fused to polyHis in pET33b and grown in BL21(DE3) or NovaBlue (DE3; Novagen, Madison, WI).
After IPTG induction, bacteria were lysed, and inclusion bodies were
solubilized in (in mM) 10 Tris, pH 8.0, 150 NaCl, 1 EGTA, 5 DTT, and 0.2 PMSF with 1.5% Sarkosyl. GST fusion proteins (~10 µg)
were batch-bound to glutathione-agarose beads (Sigma, St. Louis, MO)
in this same buffer, rocked at 4°C overnight, and washed five times
with PBS. Of the glutathione-agarose beads, 15 µl was combined with
solubilized His-tag fusion proteins (~100 µg) into 1 ml of binding
buffer [ containing (in mM) 10 HEPES, pH 7.5, 0.5 DTT, 0.5 EDTA, 150 NaCl, and 0.2 PMSF with 0.1% NP-40 and 5 mg/ml BSA],
incubated for 12 hr at 4°C, and washed three to five times with
excess binding buffer; bound proteins were batch-eluted with 30 µl of
reduced glutathione (Sigma). Eluted proteins (10 µl) were mixed with
2× loading buffer and subjected to 8% SDS-PAGE. The gel was prepared
as a Western blot and probed with either dSlo or dSLIP1 antiserum, as
described above.
Coimmunoprecipitations. COS-7 cells were transiently
transfected by using calcium phosphate; 48 hr after transfection the cells were harvested and lysed in 50 mM HEPES, pH 7.5, 100 mM NaCl, 10% glycerol, 1% Triton X-100, and 0.2 mM PMSF. After sonication, insoluble debris was removed by
a brief centrifugation, and the supernatant was incubated with
preimmune serum (5 µl) for 1 hr at 4°C. Protein A-Sepharose CL-4B
(Pharmacia) was added and incubated for an additional 3 hr at 4°C
before centrifugation in a table-top centrifuge. The supernatant was
used for coimmunoprecipitations by incubation with 3 µl of dSlo
antiserum at 4°C for 1 hr, after which 30 µl of protein
A-Sepharose CL-4B was added; the mixture was rocked overnight at
4°C. After centrifugation, the immunoprecipitate was washed
extensively with 50 mM HEPES, pH 7.5, 100 mM
NaCl, 10% glycerol, 0.1% Triton X-100, and 0.2 mM PMSF.
Antibody was eluted by the addition of 50 µl of 0.1 M
glycine, pH 2.9, and an aliquot was combined with 2× loading buffer
and subjected to 8% SDS-PAGE. The gel was prepared as a Western blot
and probed with the indicated antiserum, as described above.
Immunocytochemistry. COS-7 cells were plated onto microscope
slide coverslips and transiently transfected, using calcium phosphate, with dSlo or dSlo and dSLIP1, each subcloned in pcDNA3 (Invitrogen, San
Diego, CA). Forty-eight hours after transfection, cells were washed
three times with PBS, then fixed with 4% paraformaldehyde (for 15 min
at room temperature), washed three times with 0.1% Triton X-100 in
PBS, and washed twice with the same solution with 0.2% BSA. Cells were
preblocked with 10% horse serum and 0.1% Triton X-100 in PBS at 4°C
for 3 hr, washed once with 0.1% Triton X-100 in PBS, and incubated
overnight at 4°C with rabbit anti-dSlo antiserum (1:1000) in 0.1%
Triton X-100 in PBS. The next morning, cells were washed twice with
0.1% Triton X-100 in PBS and incubated for 2 hr with biotinylated goat
anti-rabbit secondary antibody (1:500; Vector Laboratories, Burlingame,
CA), then washed two times with 0.1% Triton X-100 in PBS, incubated
with FITC avidin D (1:200; Vector Laboratories), and finally washed
five times with PBS. Coverslips were mounted on slides, and
immunostaining was visualized with a fluorescence microscope (Leitz
Dialux 22EB, Wetzlar, Germany).
Electrophysiology. In vitro mRNA synthesis
and oocyte injections were performed as previously described (Adelman
et al., 1992). dSlo was expressed from pS (A1E1G3;
Adelman et al., 1992), dSLIP1 and dSlo-C665-1164 from pBF (generous
gift of Dr. Bernd Fakler, University of Tübingen, Tübingen,
Germany), and the noninactivating version of Shaker from pSK (generous
gift of Dr. Ligia Toro, University of California at Los Angeles, Los
Angeles, CA). Xenopus care and handling were in accordance
with the highest standards of institutional guidelines. Frogs underwent
no more than two surgeries, separated by at least three weeks, and
surgeries were performed by well established techniques. Frogs were
anesthetized with an aerated solution of 3-aminobenzoic acid ethyl
ester. Oocytes were studied 3-7 d after injection. Whole-cell currents
were measured by a two-electrode voltage clamp with a Geneclamp 500 amplifier (Axon Instruments, Foster City, CA) interfaced to a Macintosh
Quadra 800 computer. Data were acquired via Pulse (HEKA Elektronik,
Lambrecht, Germany) at 500 Hz. During recording, oocytes were
superfused continuously with ND96 solution containing (in
mM) 96 NaCl, 2 KCl, 1.8 CaCl2, 1 MgCl2, and 5 HEPES, pH 7.5 with NaOH, at room
temperature.
Inside-out macropatches were excised into an intracellular solution
containing (in mM) 116 K-gluconate, 4 KCl, and 10 HEPES, pH
7.25, adjusted with KOH supplemented with CaCl2 or EGTA or both. To obtain nominally Ca-free solution, we added 1 mM
EGTA. Alternatively, CaCl2 was added to the cytoplasmic
solution to give free calcium concentrations of 10-100
µM. In this case the proportion of calcium binding to
gluconate was determined by a computer program (CaBuf), assuming a
stability constant for Ca2+ gluconate of 15.9 M1 (Dawson et al., 1969). Electrodes were
pulled from thin-walled filamented borosilicate glass (World Precision
Instruments, Sarasota, FL) and filled with (in mM) 116 K-gluconate, 4 KCl, and 10 HEPES, pH 7.25. Electrode resistance was
typically 2-5 M . Membrane patches were voltage-clamped by an
Axopatch 200A amplifier (Axon Instruments). The data were low-pass
Bessel-filtered at 1 kHz and acquired with Pulse software (HEKA
Elektronik). Analysis was performed by Pulse and Kaleidagraph
(Abelbeck, Reading, PA) software. Macropatch currents were measured
during 500 msec voltage steps from a holding potential of 0 mV. All
experiments were performed at room temperature.
To examine single-channel properties, we used the same solutions as
those for macropatch recordings. Electrodes were pulled from Corning
7052 glass (Garner) and had resistances of 9-13 M. Data were
filtered at 1 kHz (Bessel), acquired at 10 kHz by using Pulse (HEKA
Elektronik), and stored directly on a Macintosh Quadra 650. Recordings
were analyzed by MacTac (Bruxton, Seattle, WA). The "50%
threshold" technique was used to detect openings that were inspected
visually and adjusted for their amplitude before being accepted.
Amplitude histograms were constructed by using MacTacfit (Bruxton) and
fit by a single gaussian distribution. NPo, the product of the single-channel
open probability multiplied by the number of channels, was calculated
as the sum of the dwell time × level number divided by the total
time. To calculate Po, we estimated
N as the maximum number of simultaneously open channels at
100 mV in 10 µM calcium.
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RESULTS |
Isolation of dSLIP1
The sequence encoding the C-terminal 500 amino acids of dSlo, a
region that does not vary by alternative exon choices among the known
dSlo splice variants (Atkinson et al., 1991; Adelman et al., 1992), was
used in an interaction trap (Gyuris et al., 1993) screen of a
Drosophila embryo cDNA library. From
~106 transformed cDNAs, several hundred colonies
were obtained on media lacking leucine. These were assayed individually
on galactose media for growth in the absence of leucine and
-galactosidase activity, which eliminated all but eight of the
clones. The remaining candidates were rescued, and the nucleotide
sequences of the inserts were determined. Four of the clones were
discarded; one encoded a RNA binding protein, one encoded a
transcription factor, and two contained mitochondrial DNA sequences.
The remaining four clones fulfilled the interaction trap requirements
for interactions with the C-terminal domain of dSlo, and one clone,
dSLIP1 (dSLo interacting protein), was chosen for further study (Fig.
1A; see Materials and
Methods).
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Figure 1.
A, Interaction trap selection for
dSLIP1. dSLIP1 was introduced into EGY195 containing the indicated bait
plasmids. The plate on the left shows that in the
presence of glucose and leucine all combinations permit growth, whereas
the plate on the right shows that only the combination
of dSLIP1 with dSlo-C665-1164 survives in the presence of galactose
and the absence of leucine. dSlo-C665-1164, the
C-terminal 499 amino acids of dSlo; dSlo-N1-127, the
N-terminal 127 amino acids of dSlo;
rKir3.4-C103-417, the C-terminal 314 amino acids of Kir3.4 (Krapivinsky et al.,
1995a,b). B, Full-length coding sequence of dSLIP1. The
domain recovered in the original interaction trap screen started from
amino acid 101 and extended through the coding region; potential
substrate sites for serine/threonine protein kinases are denoted by
asterisks. The domain of dSLIP1 with homology to the PDZ
domain of 1 syntrophin is overlined.
C, The dSLIP1 cDNA encodes the full-length protein. Bacterially expressed dSLIP1 (His-tag fusion protein; lane
1), in vitro translated dSLIP1 (lane
2), and Drosophila embryo proteins (lane
3) were prepared as a Western blot and probed with a polyclonal antiserum directed against recombinant dSLIP1. The dSLIP1 antiserum detected bands of similar molecular weights.
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The original dSLIP1 clone contained an open reading frame fused to the
B42 transcriptional activation domain, a stop codon, 3' untranslated
sequences, and a poly(A+) tail. However, this clone
did not contain an initiator methionine. To isolate a full-length
coding sequence, we performed 5' RACE reactions by using
Drosophila head cDNA (Bond, 1994). Analysis of the RACE
products extended the N-terminal coding sequence and identified a
putative initiator codon. The full-length coding sequence of dSLIP1
predicts a protein of 396 amino acids with five potential substrate
sequences for serine/threonine protein kinases (R/KXXT/S; Fig.
1B). Hydropathy analysis did not identify hydrophobic
domains that may span the membrane, suggesting that dSLIP1 is a
cytoplasmic protein. The dSLIP1 sequence does not show overall homology
to any other known protein, but the N terminus contains a region with
homology to the PDZ domain of 1 syntrophin (Fig.
1B; Gibson et al., 1994; Adams et al., 1995). To
confirm that the clone encoding dSLIP1 contained the full-length coding sequence, we prepared bacterially expressed dSLIP1, in vitro
translated dSLIP1, and extracts from whole Drosophila
embryos as a Western blot. Antisera specific for dSLIP1 recognized
bands of the same size (Fig. 1C) only in these samples.
dSlo and dSLIP1 mRNAs are coexpressed
in Drosophila
The expression patterns of dSlo and dSLIP1 mRNAs were compared by
using in situ hybridization on embryo whole mounts. dSlo mRNA is heavily expressed throughout the CNS as well as in several peripheral locations (Fig. 2, left,
A,B). dSLIP1 mRNA also is expressed throughout the CNS (Fig. 2,
left, C,D); dSlo and dSLIP1 mRNAs are expressed coincidently
in virtually all CNS neurons. dSLIP1 mRNA is not expressed, however, in
peripheral cell types that express dSlo mRNA. Northern blot analysis
with a dSLIP1 probe detected a single band of 3.6 kb in whole-embryo
mRNA (Fig. 2, right). The genomic location of the dSLIP1
gene was determined by probing polytene chromosome squashes with dSLIP1
sequences. Cytological examination unambiguously identified the dSLIP1
gene as residing on the fourth chromosome between bands 102C-D (data not shown). This region does not contain a high density of genetic markers, and no known mutations in this area appear to involve the
dSLIP1 gene (FlyBase).
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Figure 2.
Left, dSlo and dSLIP1 mRNAs are
expressed in a coincident pattern throughout the
Drosophila CNS. Lateral views of whole-mount in
situ hybridization in late-stage embryos of sense (A,
C) and antisense (B, D) digoxigenin-labeled
riboprobes generated from dslo (A, B) and
dSLIP1 (C, D) cDNAs. Strong hybridization of both antisense probes is present in the brain and ventral ganglion. In
contrast to dslo, hybridization of dSLIP1 is not present
in anterior sensory cells. Anterior, left; posterior,
right. Right, Northern blot analysis of
dSLIP1 mRNA. Poly(A+) mRNA (3 µg) extracted from
Drosophila embryos was prepared as a Northern blot and
probed with a full-length radiolabeled dSLIP1 riboprobe; detected was a
single band of ~3.6 kb.
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Domains mediating the interaction between dSlo and dSLIP1
The interaction between the C-terminal domain of dSlo and dSLIP1
was examined in vitro. Each protein was expressed in
bacteria and isolated as either a GST or pHis fusion protein. Pull-down experiments were performed by binding either GST-dSlo or GST-dSLIP1 proteins to a glutathione-agarose column and passing the other protein
as a polyHis fusion over the column. Bound proteins were eluted by
applying reduced glutathione, separated by polyacrylamide gel
electrophoresis, and visualized by Western blot analyses. The results
show that GST-dSLIP1 specifically retained pHis-dSlo-C665-1164 (Fig.
3A, left). The region of dSlo
that mediates the interaction with dSLIP1 was defined by similar
experiments in which different C-terminal domain fragments of dSlo were
produced as GST fusion proteins and bound to glutathione-agarose beads
before the application of pHis-dSLIP1 protein. The results demonstrate
that inclusion of the region of dSlo between amino acids 1032 and 1164 retained dSLIP1 protein, whereas further deletion abolished the
interaction (Fig. 3A, right). Similar results were obtained
by complementary two-hybrid analyses. To localize more precisely the
domain of dSLIP1 that mediates the interaction with dSlo, we performed
two-hybrid experiments with dSlo-C665-1164 and different
regions of dSLIP1. These experiments localized the
interacting domain to the C-terminal 100 residues of dSLIP1; further
deletions from either end resulted in loss of the interaction
(Tables 1,
2).
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Figure 3.
GST pull-down experiments show the interaction
between dSlo and dSLIP1. GST fusion proteins, indicated
above the blots, were bound to glutathione-agarose
beads, and pHis-dSlo (top, left) or
pHis-dSLIP1 (top, right) protein was
applied. After several washes, retained proteins were eluted with
reduced glutathione and prepared as a Western blot. A,
Left, Western blot probed with dSlo antibodies.
Lane 1 (Control), Bacterially
expressed pHis-dSlo-C665-1164 protein, as marker.
pHis-dSlo-C665-1164 protein was retained by GST-dSLIP1 (lane
2), but not by GST alone (lane 3).
Right, Western blot probed with dSLIP1 antibodies.
Lane 1, Bacterially expressed pHis-dSLIP1 alone as
marker; lanes 2-9, pHis-dSLIP1 was retained by
GST-dSlo-C654-1164 or GST-dSlo-C-1032-1164, but not by other C-terminal fragments of dSlo or by GST alone. B,
Antibodies to dSlo coimmunoprecipitate dSLIP1 from cotransfected COS-7
cells. Western blot was probed with dSLIP1 antibodies. Lane
1, In vitro translated dSLIP1; lane
2, proteins immunoprecipitated with dSLIP1 antibodies;
lane 3, proteins immunoprecipitated with dSlo
antibodies; lane 4, proteins immunoprecipitated with
FLAG antibodies.
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dSlo antibody coimmunoprecipitates dSLIP1
The pull-down experiments indicated a stable interaction in
vitro between dSlo-C665-1164 and dSLIP1. Therefore, dSlo and
dSLIP1 were transiently cotransfected into COS-7 cells, and total
cellular proteins were used for immunoprecipitations with antibodies
directed against either dSlo, dSLIP1, or FLAG (control).
Immunoprecipitated proteins were prepared as a Western blot and probed
with dSLIP1 antibodies. Figure 3B shows that
immunoprecipitations with dSlo antibodies coprecipitated dSLIP1.
dSLIP1 decreases dSlo current amplitudes
Functional interactions between dSlo and dSLIP1 were examined in
inside-out patches from Xenopus oocytes expressing either dSlo alone or dSlo and dSLIP1. Before injection, in vitro
synthesized dSLIP and dSlo-C665-1164 mRNAs were adjusted to equal
approximately molar ratios on the basis of spectrophotometric and
agarose gel analyses, while dSlo mRNA was injected at three- to
fivefold lower concentrations. Current amplitudes were measured at 100 mV in the presence of 10 µM internal
Ca2+, using electrodes of similar resistances (~3
M). In a representative experiment (Fig.
4A), patches from
dSlo-expressing oocytes had current amplitudes of 3.0 ± 2.5 nA
(n = 21), whereas similar patches from oocytes
coexpressing dSlo and dSLIP1 showed current amplitudes of 0.8 ± 1.9 nA (n = 21; p < 0.005). The
reduction in patch current was specific for the interaction between
dSlo and dSLIP1 because the effect was reversed by coexpression with
dSlo-C665-1164, the fragment used to screen for dSLIP1. In the
experiment shown, current amplitudes in patches from oocytes expressing
dSlo, dSLIP1, and dSlo-C665-1164 were no different from those for dSlo
alone, 3.6 ± 1.9 nA (n = 18; p > 0.1). dSlo current reduction by coexpression with dSLIP1 gave similar
results in 12 of 15 experiments that used different batches of oocytes;
the average reduction was 71 ± 18%. In seven batches of oocytes,
inhibition of this effect by dSlo-C665-1164 was examined; the current
was rescued at least partially in six batches, resulting in a 3.4 ± 1.1-fold increase in the average patch current as compared with
oocytes expressing only dSlo and dSLIP1. There was no effect of
dSlo-C665-1164 on dSlo current amplitudes (1.7 ± 0.8 nA,
n = 9 vs 2.0 ± 1.2, n = 11;
p > 0.5). In three of five experiments in which the
human BK channel, hSlo, was substituted for dSlo, the same specific inhibitory effect of dSLIP1 was observed (Fig. 4B).
On average, the current seen in oocytes expressing hSlo and dSLIP1 was
reduced by 69 ± 10% as compared with oocytes expressing only
hSlo. Oocytes expressing hSlo, dSLIP1, and dSlo-C665-1164 displayed a
2.4 ± 1.1-fold increase in current as compared with oocytes
expressing hSlo and dSLIP1. In contrast, dSLIP1 did not reduce currents
in oocytes expressing Shaker channels (Fig. 4C). The effect
of dSLIP1 on Slo currents was sensitive to the amount of Slo mRNA
injected. When Slo mRNA was injected in excess to dSLIP1, the reduction in current amplitude was reduced or eliminated.
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Figure 4.
Coexpression with dSLIP1 reduces BK current
amplitudes. Current amplitudes at 100 mV were determined in inside-out
patches from oocytes excised into 10 µM
Ca2+ (A, B) or by
using the two-electrode voltage clamp (C).
Oocytes expressed dSlo (A), hSlo
(B), or Shaker (C) channels
either alone (left columns) or in combination with
dSLIP1 (middle columns) or with dSLIP1 and
dSlo-C665-1164 (right columns). Patch currents are
shown as box plots in which the median is represented by
a line separating the upper and lower quartiles (UQ,
LQ). The box (interquartile distance, IQD) contains ± 25% of the data points; the error bars mark the minimum and maximum
values that fall within UQ + 1.5 × IQD and LQ + 1.5 × IQD.
The outliers in A and B were recorded
from a single oocyte in each case. The numbers of patches in each plot
were 21 for dSlo and dSlo + dSLIP1, 18 for dSlo + dSLIP1 + dSlo-C665-1164, and 15 for hSlo, hSlo + dSLIP1 and for hSlo + dSLIP1 + dSlo-C665-1164. Also examined were 11 oocytes expressing Shaker or
Shaker + dSLIP1 and 6 oocytes expressing Shaker + dSLIP1 + dSlo-C665-1164.
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|
To investigate whether the reduction of patch current at a given
voltage and calcium concentration was attributable to a reduced calcium
sensitivity of dSlo channels in the presence of dSLIP1, we measured the
patch conductance holding at  100 to +100 mV in three concentrations
of intracellular Ca2+ for patches expressing dSlo
alone (Fig. 5A) or together
with dSLIP1 (Fig. 5B). Data were fit to a Boltzmann
relationship, and the resulting values for the voltage of
half-activation (V0.5) were averaged for
three to five patches and plotted as a function of
Ca2+ concentration in Figure 5C; no
significant differences were observed at any of the
Ca2+ concentrations that were examined.
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|
Figure 5.
dSLIP1 does not change the calcium dependence of
dSlo. Excised patches from oocytes expressing dSlo
(A), dSlo and dSLIP1 (B), or dSlo, dSLIP1, and dSlo-C665-1164 were exposed to 10, 30, and 100 µM free Ca2+. Patch conductance was
determined by dividing the steady-state current during a 500 msec
voltage step by the holding potential. Data were fit to a Boltzmann
equation of the form I = Imax/(1 + exp k · (V V0.5)).
C, The resulting potentials of half-activation (V0.5) were averaged for three to
five patches and plotted as a function of Ca2+
concentration; error bars represent SE.
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To investigate further the mechanism underlying the reduction in Slo
currents mediated by dSLIP1, we examined single hSlo channels. Channels
from oocytes injected either with hSlo alone or with hSlo and dSLIP1
were exposed to 100 µM Ca2+ and showed
the same single-channel amplitude as a function of voltage (Fig.
6A,B). The average
single-channel conductance was 242 ± 16 pS in three patches with
hSlo alone and 224 ± 5 pS in four patches with hSlo and dSLIP1
(p > 0.05). The open probability (Po) as a function of voltage also was
not affected by coexpression with dSLIP1 (Fig. 6C), further
confirming that dSLIP1 did not affect the calcium sensitivity of hSlo
channels.
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Figure 6.
Coexpression with dSLIP1 does not affect the
single-channel conductance or the open probability of hSlo channels.
A, Traces (1 sec) of steady-state recordings from
patches excised from an oocyte expressing hSlo (left) or
hSlo and dSLIP1 (right). Patches were exposed to 100 µM free Ca2+ and held at +60 mV
(top) or 40 mV (bottom). Both patches
contained two channels; the closed levels are indicated on the
left. B, Single-channel amplitudes as a
function of voltage in two patches containing two channels
(filled circles, same patch as A)
or a single-channel (open squares) from an oocyte
expressing hSlo or hSlo and dSLIP1, respectively. Amplitudes were
determined by fitting gaussian distributions to amplitude histograms
representing at least 1000 events. Linear regression analysis yielded
single-channel conductances of 227 pS for hSlo and 226 pS for hSlo and
dSLIP1. C, Single-channel open probability as a function
of voltage for the two patches in B.
|
|
Because the gating and conduction properties of Slo channels were
not obviously affected by dSLIP1, the reduction in macroscopic current
amplitudes probably resulted from a reduced number of channels in the
plasma membrane. This possibility was examined further by
immunocytochemistry with dSlo antiserum on COS-7 cells that had been
transfected with dSlo alone or together with dSLIP1. In cells
expressing only dSlo, a reticular punctate staining pattern was
obtained, with dSlo immunoreactivity clearly seen on the outer membranes (Fig. 7, left). In
contrast, cotransfected cells showed diffuse internal staining with
little, if any, dSlo immunoreactivity on the cell surface (Fig. 7,
right).
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Figure 7.
Immunostaining of COS-7 cells. COS-7 cells
transiently transfected with dSlo (left) or
cotransfected with dSlo and dSLIP1 (right) were
immunostained with dSlo antiserum. Cells expressing dSlo show only a
reticular punctate staining pattern with clear cell surface staining,
whereas cells transfected with dSlo and dSLIP1 show a diffuse
intracellular staining pattern.
|
|
| |
DISCUSSION |
The results presented here demonstrate that dSLIP1 selectively
interacts with the C-terminal domain of BK channels. When coexpressed in Xenopus oocytes, dSLIP1 reduces macroscopic BK currents
as compared with expression of BK channels alone, without affecting unit current amplitude (I) or open probability
(Po). Taken together with
immunocytochemical results from cotransfected COS-7 cells, it is likely
that dSLIP1 limits the number of functional BK channels in the plasma
membrane.
Mechanisms for regulating channel density will have significant effects
on neurons and other excitable cells. For neuronal sodium channels,
intracellular pools of the -subunit appear before the emergence of
functional sodium channels on the cell surface, and it is likely that
maturation, translocation, and plasmalemmal insertion are accompanied
by association with -subunits (Scheinman, 1989; Sutkowski and
Catterall, 1990; Isom et al., 1995). A similar mechanism may operate in
cardiac myocytes (Qu et al., 1995). Coexpression of calcium channel
- and -subunits increases the amplitudes of the currents and the
number of high-affinity drug and toxin-binding sites as compared with
expression of -subunits alone (Mori et al., 1991; Williams et al.,
1992; Stea, 1993). Voltage-gated potassium channels may associate with
one or more -subunits. The 2 subunit acts as a chaperone,
regulating channel density and current amplitude by increasing the
number of channels in the plasma membrane (Rettig et al., 1994; Shi et
al., 1996).
For BK channels, post-translational regulation of current density is
well documented in developing parasympathetic neurons such as chick
ciliary ganglia (CG). In developing CG, or in cultured CG in the
absence of target tissue, BK channel mRNA is present, but no BK
currents are detected. However, when CG neurons are cultured in the
presence of target tissue extract, BK channel activity appears, and
this regulation is independent of protein synthesis (Subramony et al.,
1996; Subramony and Dryer, 1997). Although the underlying mechanisms
have not yet been elucidated, the results are consistent with a
regulated interaction, in the absence of target tissue, between
intracellular BK channels and a dSLIP1 homolog.
These studies implicate post-translational mechanisms for the regulated
appearance of functional channels in the plasma membrane. dSLIP1 may
represent a component of such a system, retaining BK channel
-subunits in an intracellular pool until a physiological cue induces
translocation into the plasma membrane. In our studies the effects of
dSLIP1 may be overcome by the additional expression of BK -subunits,
suggesting the possibility that one molecule of dSlo binds to several
(four?) molecules of dSLIP1.
The C-terminal domain of dSLIP1 is required for the interactions with
BK -subunits, whereas the N-terminal domain of dSLIP1 has limited
homology with the PDZ domain of 1 syntrophin, which has been shown
to bind nitric oxide synthase and has been implicated in calcium
binding (Brenman et al., 1996; Newbell et al., 1997). Similarly, this
domain of dSLIP1 may mediate interactions with additional regulatory
components, perhaps in a calcium-dependent manner.
| |
FOOTNOTES |
Received Nov. 3, 1997; revised Jan. 12, 1998; accepted Jan. 15, 1998.
This work was supported by National Institutes of Health grants to
J.P.A. We thank our colleagues Jim Maylie, Chris Bond, Ian Roberts,
Bill Wolfgang, and Stan Hollenberg for fruitful discussions. We also
thank Erica Golemis and Roger Brent for supplying interaction trap
reagents before their publication and for continued technical advice
during the course of these experiments.
Correspondence should be addressed to Dr. John P. Adelman, Vollum
Institute, Oregon Health Sciences University, Portland, OR 97201.
| |
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Top
Abstract
Introduction
