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The Journal of Neuroscience, October 1, 2001, 21(19):7517-7525
Contactin Associates with Na+ Channels and Increases
Their Functional Expression
Katie
Kazarinova-Noyes1,
Jyoti Dhar
Malhotra2,
Dyke
P.
McEwen2,
Laura N.
Mattei2,
Erik O.
Berglund3,
Barbara
Ranscht3,
S. Rock
Levinson4,
Melitta
Schachner5,
Peter
Shrager1,
Lori L.
Isom2, and
Zhi-Cheng
Xiao1
1 Departments of Neurobiology/Anatomy and
Biochemistry/Biophysics, University of Rochester Medical Center,
Rochester, New York 14642, 2 Department of Pharmacology,
University of Michigan, Ann Arbor, Michigan 48109-0632, 3 Neuroscience Program, The Burnham Institute, La Jolla,
California 92037, 4 Department of Physiology, University of
Colorado Health Sciences Center, Denver, Colorado 80262, and
5 Zentrum fuer Molekulare Neurobiologie, Universitat
Hamburg, D-20246 Hamburg, Germany
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ABSTRACT |
Contactin (also known as F3, F11) is a surface glycoprotein
that has significant homology with the  2 subunit of voltage-gated Na+ channels. Contactin and Na+
channels can be reciprocally coimmunoprecipitated from brain homogenates, indicating association within a complex. Cells
cotransfected with Na+ channel Nav1.2
and 1 subunits and contactin have threefold to fourfold higher peak
Na+ currents than cells with Nav1.2
alone, Nav1.2/1, Nav1.2/contactin, or
Nav1.2/1/2. These cells also have a correspondingly
higher saxitoxin binding, suggesting an increased
Na+ channel surface membrane density.
Coimmunoprecipitation of different subunits from cell lines shows that
contactin interacts specifically with the 1 subunit. In the PNS,
immunocytochemical studies show a transient colocalization of contactin
and Na+ channels at new nodes of Ranvier forming
during remyelination. In the CNS, there is a particularly high level of
colocalization of Na+ channels and contactin at
nodes both during development and in the adult. Contactin may thus
significantly influence the functional expression and distribution of
Na+ channels in neurons.
Key words:
contactin; node of Ranvier; Na+
channel; subunit; axon; cluster
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INTRODUCTION |
The function of excitable cells is
highly dependent on regulation of surface density and biochemical
modulation of ion channels. In neurons, voltage-gated
Na+ channels are clustered within axonal initial
segments and nodes of Ranvier, in which they serve to initiate action
potentials. This distribution requires control of biosynthesis,
targeting to specific axonal regions, and anchoring to the
cytoskeleton. Although much is known about each of these processes,
important details are lacking. Mammalian Na+
channels are heteromultimeric structures that include the pore-forming subunit in association with auxiliary subunits. At present, three subunits and one splice variant have been identified and shown to modulate expression and voltage dependence (Isom
et al., 1994 , 1995a,b; Kazen-Gillespie et al.,
2000; Morgan et al., 2000). 1 is
noncovalently associated with , whereas 2 is covalently linked to
the subunit by disulfide bonds. 3 is highly homologous to 1.
These channels, however, exist in an even larger molecular complex that
may include both cis (axonal) and trans (glial)
elements. It has been shown, for example, that axonal
Na+ channels associate with ankyrin G, providing a
link to cytoskeletal elements (Bennett and Lambert,
1999).
In this study, we focused on contactin as a possible member of the
Na+ channel signaling complex. Contactin (also known
as F3, F11 in various species) is a glycosyl-phosphatidylinositol
(GPI)-anchored protein expressed by neurons and glia that is thought to
play multiple roles in the nervous system (Ranscht et al.,
1984; Ranscht, 1988; Brummendorf et al.,
1989; Gennarini et al., 1989; Koch et al., 1997). We were initially drawn to this study by the
structural similarity of contactin to Na+ channel
2 subunits. The extracellular region of contactin includes four
fibronectin type III domains and six Ig-like domains. 2 subunits are
transmembrane proteins with a single Ig-type domain in their
extracellular regions. The Ig domain of 2 has sequence homology to
the third Ig domain of contactin, and the extracellular juxtamembrane
regions of these proteins are also homologous (Isom et al.,
1995b; Isom and Catterall, 1996). Furthermore,
tenascin-R, which accumulates at nodes of Ranvier in the CNS, binds to
the Ig-like domains of contactin (Pesheva et al., 1993;
Xiao et al., 1996, 1997, 1998), as well as to 2
(Srinivasan et al., 1998; Xiao et al.,
1999). Contactin also interacts with receptor protein tyrosine
phosphatase , a protein that is expressed by glia, but may also be
neuronal, and has been shown to modulate Na+ channel
function through binding to or 1 subunits (Peles et al.,
1995; Ratcliffe et al., 2000). Contactin is also
linked to the localization of axonal ion channels through its
association with contactin-associated protein (Caspr)/paranodin,
a neurexin family protein that forms part of the axoglial junctions at
paranodes (Einheber et al., 1997; Menegoz et al.,
1997; Peles et al., 1997; Faivre-Sarrailh
et al., 2000; Rios et al., 2000) and whose
expression precedes Na+ channel clustering in the
optic nerve (Rasband et al., 1999). Thus, numerous lines
of evidence indicate a role for contactin in regulating surface
expression of Na+ channels. A combination of
biochemical, electrophysiological, and immunolocalization experiments
all point to a specific association of contactin with
Na+ channels that can act to regulate their
functional expression.
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MATERIALS AND METHODS |
Antibodies. Three anti-Na+ channel
antibodies, all against the same conserved peptide antigen within the
intracellular loop between domains III and IV of the subunit, were
used with similar results. These antibodies were as follows: an
affinity-purified polyclonal antibody (Dugandzija-Novakovic et
al., 1995); a monoclonal antibody (Rasband et al.,
1999); and an anti-SP19 polyclonal antibody obtained from
Alomone Labs (Jerusalem, Israel). Rabbit polyclonal antisera to an
extracellular domain of 1 (KRRSETTAETFTEWTFR), "1EX," and the cytoplasmic domain of 2
(KCVRRKKEQKLSTD) were described previously (Malhotra et al.,
2000). Polyclonal antiserum to an intracellular domain of 1
(LAITSESKENCTGVQVAE), "1IN," was generated
and affinity purified by Research Genetics (Huntsville, AL). Polyclonal
anti-contactin antibodies were raised against Ig domains 1-6 and were
affinity purified for immunocytochemistry (Berglund et al.,
1999). Monoclonal anti-myelin associated glycoprotein (MAG)
antibodies were prepared as described previously (Poltorak et
al., 1987). Monoclonal anti-neurofilament and anti--coatomer protein (COP) antibodies were obtained from Sigma (St. Louis, MO). Secondary antibodies were purchased from Accurate Chemical and
Scientific Corp. (Westbury, NY) and Molecular Probes (Eugene, OR).
Coimmunoprecipitation. Brain membranes were prepared as
described previously (Isom et al., 1995b). Membranes
were solubilized in 1.25% Triton X-100, and the soluble fraction was
incubated overnight at 4°C with 1 µg of primary anti- subunit
antibody. Stably transfected cell lines coexpressing contactin and
Nav1.2, contactin and 2, or contactin and 1 were
grown for 24 h after confluencey before harvesting with 50 mM Tris and 10 mM EDTA, pH 8.0. Cell pellets
were resuspended and solubilized in 1.25% Triton X-100, and the
soluble fraction was incubated for 4 hr at 4°C with 1 µg of
anti-, anti-2, or anti-1 antibodies, respectively. Protein A
Sepharose beads (50 µl of a 1:1 suspension) were then added, and the
incubation continued for 2 hr at 4°C. The beads were washed with 50 mM Tris HCl, pH 7.5, containing 0.1% Triton X-100 and
protease inhibitors. Immunoprecipitated proteins were eluted from the
beads with SDS-PAGE sample buffer and separated on 7.5% acrylamide
SDS-PAGE gels. Proteins were transferred to nitrocellulose and probed
with anti-contactin antibody (1:1000). Chemiluminescent detection of
immunoreactive bands was accomplished with WestDura reagent (Pierce,
Rockford, IL).
Transfection and characterization of cell lines. Chinese
hamster lung (CHL)/1610 cells were obtained from the American Type Culture Collection (Manassas, VA). 1610 cells expressing type Nav1.2 subunits alone or and 1 subunits were
prepared by transfection with the appropriate cDNAs using
N-[1-(2,3-dioleoyloxy)propyl]-N,N,N-trimethylammonium methyl sulfate (DOTAP) (Roche Products, Hertforshire, UK), as described previously (West et al., 1992; Isom et
al., 1995b), and were obtained as a generous gift from the
laboratory of W. A. Catterall (University of Washington, Seattle,
WA). These cells, originally named SNaIIA and SNaIIA1-16,
respectively, are denoted Nav1.2 and
Nav1.2/1 here to emphasize their subunit composition. A
mammalian expression vector for mouse contactin cDNA, pRc/CMV.F3, was a
generous gift from Dr. Genevieve Rougon (Centre National de la
Recherche Scientifique, Marseille, France). 1610 cells were transfected with 10 µg of pRc/CMV.F3 using DOTAP as above.
Nav1.2 and Nav1.2/1 cells were cotransfected
with pRc/CMV.F3 and pcDNA3.1-Zeo (Invitrogen, Carlsbad, CA) because
both of these cell lines were already resistant to G418 and were
selected with 400 µg/ml G418 (Life Technologies, Gaithersburg, MD)
for 1610 cells or 400 µg/ml Zeocin (Invitrogen) plus 200 µg/ml G418 for Nav1.2/contactin and Nav1.2/1/contactin cells. Nav1.2/1/2
cells were prepared by transfection of Nav1.2/1 cells
with pcDNA3.1Zeo(+)2 and were selected with 400 µg/ml Zeocin.
1/contactin and 2/contactin cells were prepared by transfection
with 5 µg of pcDNA3.1-Zeo(+)1 or pcDNA3.1-Zeo(+)2,
respectively, using Lipofectamine 2000 (Life Technologies) and were
selected with 400 µg/ml Zeocin plus 200 µg/ml G418.
Nav1.2/2/contactin cells were prepared by transfection of Nav1.2/contactin cells with pcDNA3.1-Hygro(+)2 using
Lipofectamine 2000 and were selected with 400 µg/ml Hygromycin B
(Life Technologies) plus 200 µg/ml Zeocin plus 200 µg/ml G418.
Nav1.2/1/2/contactin cells were prepared by
transfection of Nav1.2/1/contactin cells with 5 µg of
pcDNA3.1-Hygro(+)2 using Lipofectamine 2000 and were selected with
400 µg/ml Hygromycin B plus 200 µg/ml Zeocin plus 200 µg/ml G418.
Drug-resistant colonies were expanded, and total RNA was prepared using
Trizol reagent (Life Technologies). For Northern blot analysis, 10 µg
of each sample was separated on 1% agarose-formaldehyde gels and
blotted to nylon membranes as described previously (Isom et al.,
1995a). A digoxigenin-labeled (Roche Products) antisense RNA
probe was prepared from HindIII-linearized pRC/CMV.F3 and
SP6 RNA polymerase (Invitrogen), as described previously (Isom
et al., 1995a). Northern blots were detected with CDP-Star (Roche Products) and exposed to Hyperfilm ECL (Amersham Pharmacia Biotech, Arlington Heights, IL) for approximately 15 min at room temperature. Clones that were positive for contactin mRNA were expanded. For Western blot analysis, proteins were separated on 7.5 or
12% polyacrylamide gels, transferred to nitrocellulose, and probed
with appropriate antibodies as indicated. Detection was with WestDura
chemiluminescent reagent (Pierce). For electrophysiology, microcover
glasses were pretreated with UV for 4 hr, incubated with PBS containing
0.01% poly-L-lysine as described previously (Xiao
et al., 1996), washed with PBS, and dried under a sterile hood.
Cells were applied to the coated coverslips and cultured for 72 hr at
37°C before use.
Whole-cell patch-clamp recordings. Coverslips with plated
cells were placed in a recording chamber that was perfused with oxygenated Locke's solution containing (mM): 154 NaCl, 5.6 KCl, 2 CaCl2, 5 D-glucose, and 10 HEPES,
pH 7.4. Electrodes were filled with (mM): 140 CsCl, 1 CaCl2, 2 MgCl2, 11 EGTA, and 10 HEPES, pH 7.2. Whole-cell recordings were made at room temperature with an Axopatch 200A amplifier (Axon Instruments, Foster City, CA). An attempt was made to select single cells of similar size and shape
from the edges of each cultured cell population for recording. The
investigator was blinded to the cell type. Pipette and whole-cell capacitance and series resistance were corrected using the compensation circuitry of the amplifier. Small residual capacitative transients and
leak currents were subtracted using hyperpolarizing test pulses. A
laboratory computer was used to generate voltage protocols and to
record and analyze currents. Typically, records were made first by
generating a family of test pulses from a holding potential of  70 mV.
The holding potential was then hyperpolarized in 20 mV steps to
remove resting Na+ channel inactivation, and a new
family was recorded. This procedure was repeated until peak currents
reached a maximum level.
Demyelination. Lysolecithin-induced demyelination was
performed as described previously (Hall and Gregson,
1971; Shrager, 1988, 1989). Briefly, adult
female Lewis rats were anesthesized with chloral hydrate-pentobarbitol
(0.35 ml per 100 gm of animal weight), and the sciatic nerve in one leg
was surgically exposed. Several branches were each injected with 1 µl
of 1% lysolecithin in sterile Locke's solution using a glass
micropipette broken to a tip diameter of ~20 µm. The wound was
closed, and the animal allowed to recover. Nine to 70 d later, the
animal was killed by CO2 asphyxiation, and the sciatic
nerve was dissected.
Immunofluorescence. CHL cells transfected with various
components were fixed in 4% paraformaldehyde for 10 min and blocked with 5% calf serum in Tris-buffered saline. The primary anti-contactin antibody was used at 1:500, followed by a fluorescein-tagged secondary antibody (Vector Laboratories, Burlingame, CA). Slides were viewed on a
Bio-Rad (Hercules, CA) MRC 600 confocal microscope.
Sciatic nerves from demyelinated or developing animals were dissected,
desheathed, and dissociated into single fibers with collagenase-dispase (3.5 mg/ml; Sigma). In most cases, axons were teased over coverslips coated with drops of Cell-Tak (Collaborative Research, Bedford, MA), and fixed in 4% paraformaldehyde in 0.1 M phosphate buffer (PB) for 30 min. Alternative
procedures were used as controls or tests. In some preparations, nerves
were fixed before teasing; results were identical in both procedures.
To test for the possibility of antibody capping of GPI-anchored
proteins, some preparations were fixed in 4% paraformaldehyde for 5 min, followed by methanol for 5 min at 20°C (Harder et al.,
1998). After fixation, axons were washed in 0.1 M
PB, pH 7.4, for 10 min, air-dried, and permeabilized for 2 hr in 0.1 M PB containing 0.3% Triton X-100 and 10% goat serum
(PBTGS). Between steps involving antibodies, preparations were washed
three times for 5 min each with PBTGS. Axons were generally
double-labeled, and all antibodies were diluted in PBTGS. In one
series, the Triton X-100 was eliminated from all solutions. The tissue
was typically first incubated overnight with the polyclonal primary
antibody, followed by a secondary goat anti-rabbit antibody coupled to
Alexa488 (1:500; Molecular Probes). Axons were then exposed to the
monoclonal primary antibody and labeled with an anti-mouse secondary
coupled to Cy3 (1:500; Accurate Chemicals). The preparations were
allowed to air-dry and were mounted on slides using an anti-fade
mounting medium. Fibers were observed under a Nikon (Tokyo, Japan)
Microphot fluorescence microscope fitted with a Hamamatsu (Bridgewater,
NJ) C4742-95 cooled CCD video camera. Images were collected in a
laboratory computer using Image-Pro (Media Cybernetics, Silver Spring, MD).
CNS preparations were examined in cryosections. For brain sections,
Lewis rats were anesthetized as above and perfused with saline
containing 1% heparin, followed by 4% paraformaldehyde for 10 min
before dissection. Regions of the motor cortex and underlying white
matter were then cut into 2 mm sections, post-fixed in 4%
paraformaldehyde in 0.1 M phosphate buffer for 50 min,
followed by 10 min in methanol at 4°C. After washing in PB, the
tissue was cryoprotected successively in 20 and 30% sucrose, frozen in OCT medium (Miller), and cut in 15-µm-thick sections. Sections were
placed in 0.1 M PB, spread over gelatin-coated coverslips, and allowed to air dry. Optic nerves were dissected, fixed in 4%
paraformaldehyde in 0.1 M phosphate buffer for 10 min, in
methanol at 4°C for 10 min, and then treated as for brain sections.
CNS sections were permeabilized and immunolabeled as for PNS tissue.
3H-Saxitoxin binding analysis. Whole-cell
saturation binding analysis of each cell line was performed using a
vacuum filtration method as described previously (Isom et al.,
1995b) at a concentration of 5 nM
3H-saxitoxin (STX) with the addition of 10 µM
unlabeled tetrodotoxin (Calbiochem, San Diego, CA) to assess
nonspecific binding. 3H-STX (28 Ci/mmol) was obtained from
Amersham Pharmacia Biotech. Binding data were normalized to protein
concentrations using the BCA Protein Assay kit (Pierce).
Data analysis. Data were expressed as means ± SEM, and
statistical comparisons between groups were made with Student's
two-tailed t test.
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RESULTS |
Coimmunoprecipitation
A possible association between Na+ channels and
contactin was explored with coimmunoprecipitation. Rat brain membrane
preparations were solubilized in Triton X-100 and were
immunoprecipitated with anti-Na+ channel antibodies
or control antisera. Western blot analysis with an anti-contactin
antibody showed that both the lysate and the
anti-Na+ channel immunoprecipitate contained
contactin (Fig. 1a, lanes 2, 4). Control
immunoprecipitates with nonimmune IgG (lane 1) or with
antibody preabsorbed with the Na+ channel peptide
antigen (lane 3) were negative for contactin. Because equal
amounts of lysate were used in lanes 2 and 4, the difference in band densities suggests that only a fraction of the
contactin in brain may be associated with Na+
channels. The reverse coimmunoprecipitation experiment also provided evidence for association. In Figure 1b, membranes were
precipitated with either nonimmune IgG (left) or
anti-contactin antibodies (right), and the blot was probed
with anti-Na+ channel antibodies. Thus, at least a
portion of the contactin expressed in the CNS is associated with the
Na+ channel complex.
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Figure 1.
Association of contactin and
Na+ channels in brain and contactin expression in
transfected cells. a, Coimmunoprecipitation of the brain
lysate with anti-Na+ channel antibodies, probed with
anti-contactin antibodies. Lane 1, Nonimmune IgG beads as a
control; lane 2, anti-Na+ channel
(NaCh) antibodies; lane 3,
anti-Na+ channel antibodies preabsorbed with the
peptide antigen; lane 4, lysate. The bands at ~135 kDa
represent contactin. Equal amounts of lysate were used in lane
4 and in the coimmunoprecipitation reaction. The dark bands at
lower molecular weight in lanes 1-3 represent the
antibody used for immunoprecipitation. b,
Coimmunoprecipitation of brain with anti-contactin, probed with
anti-Na+ channel antibodies. Left lane,
Nonimmune IgG; right lane, anti-contactin. c-g,
Analysis of contactin expression in transfected cells. c,
Western blots of cell lines probed with anti-contactin antibodies.
Lanes 1 and 2, Two clones of
Nav1.2/1/contactin; lane 3,
Nav1.2/contactin; lane 4, 1610 cells
(untransfected). d-g, Immunocytochemistry of contactin
expressed in transfected cells. d,
Nav1.2/contactin. e, f, Two clones of
Nav1.2/1/contactin. g, Untransfected 1610 cells. Scale bar, 10 µm.
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Na+ currents in transfected cells
To test for a functional interdependence of
Na+ channels and contactin, CHL/1610 cells with
stable transfections of various combinations of Na+
channel Nav1.2 (SNaIIA) and subunits were
transfected with the contactin vector pRC/CMV.F3, and mRNA was analyzed
in Northern blots (data not shown). Untransfected 1610 cells did not
express endogenous contactin mRNA. Cell lines with a high level of
expression of contactin were selected for additional experiments.
Expression of contactin protein was documented by both Western blots
(Fig. 1c) and immunocytochemistry (Fig. 1d-g).
In the immunocytochemistry, no permeabilization reagent was used, and
the label thus represents surface expression of contactin.
Figure 2 shows families of
Na+ currents recorded under whole-cell patch clamp
from cells with transfection combinations indicated at the
left. Cells were typically held first at 70 mV, and a family of currents was recorded (Fig. 2, left column).
Compared with cells transfected with Nav1.2 subunits
alone (top records), adding either contactin or 1
subunits individually produced little change in peak current. Adding
2 to Nav1.2/1 also had relatively little effect.
Notably, however, peak inward currents in cells transfected with
Nav1.2/1/contactin were significantly larger than those
in all other cell lines. The 2 subunit had inhibitory properties on
peak currents when it was expressed together with contactin. First,
Na+ currents were virtually eliminated in
Nav1.2 /2/contactin transfected cells. Furthermore,
although the Nav1.2/1/contactin cells had the largest
Na+ currents, the addition of 2 lowered peak
INa to levels comparable with the other
transfection combinations. Na+ current amplitude is
sensitive to the level of steady-state inactivation present immediately
before application of a test pulse. To judge a possible role of
inactivation in determining Na+ currents in the
various transfected lines, especially the much larger currents in
Nav1.2/1/contactin cells, the holding potential (HP) was
hyperpolarized by 20 mV, and a new family of Na+
currents was recorded. This procedure was repeated until
Na+ current amplitudes reached a maximum level,
typically at HP of 90 or 110 mV. We compared first the five cell
lines at the top of Figure 2. As seen in the right
column, peak currents increased significantly with hyperpolarized
holding potentials in all of these cells. The ratio of maximum peak
inward current at the most negative holding potential applied to that
at a holding potential of 70 mV was 3.0 for Nav1.2 cells,
3.3 for Nav1.2/contactin, 4.0 for Nav1.2/1,
4.6 for Nav1.2/1/2, and 3.7 for
Nav1.2/1/contactin (numbers are averages of all cells
tested within each category). These numbers are all in the same range,
and the ratio for Nav1.2/1/contactin (3.7) is identical
to the average of the other four cell lines. Thus, the higher peak
currents in Nav1.2/1/contactin cells are not
attributable to a difference in resting inactivation of
Na+ channels.
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Figure 2.
Na+ currents from transfected
cells. Families of currents were recorded under whole-cell patch
clamp at different HP: left, 70 mV;
right, 90 mV, except for
Nav1.2/1/2/contactin, which were at 110 mV. Test
voltages were varied in increments of 10 mV within the following ranges
(chosen to bracket the maximum peak current, which was generally
recorded close to 0 mV): Nav1.2,
Nav1.2/contactin, Nav1.2/1/contactin, 30
to +30 (HP of 70 mV), 50 to +30 (HP of 90 mV);
Nav1.2/2/contactin, 20 to +20 (HP of 70 mV), 20 to
+20 (HP of 90 mV); Nav1.2/1,
Nav1.2/1/2, 20 to +30 (HP of 70 mV), 40 to +30
(HP of 90 mV); Nav1.2/1/2/contactin, 20 to +30
(HP of 70 mV), 30 to +40 (HP of 110 mV).
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Results for current amplitudes are summarized in Figure
3a, in which the mean peak
Na+ current density for each of the cell lines
tested is plotted. Hyperpolarized holding potentials were used to
promote opening of all channels expressed at the surface. There was a
modest increase over values with Nav1.2 alone when 1
subunits were coexpressed, but there was a fourfold increase with the
combination Nav1.2/1/contactin. This was not
attributable to variations in cell capacitance, because the average
values of this parameter for Nav1.2,
Nav1.2/1, Nav1.2/contactin, and
Nav1.2/1/contactin cells were 27, 28, 29, and 27 pF,
respectively. It was also not attributable to an unusual property of
one specific clone because the data in Figure 3a include
cells from three different clones of the
Nav1.2/1/contactin transfection group, and each alone
had similarly high currents. Peak
gNa-V curves also showed a fourfold
to fivefold higher maximum conductance in the
Nav1.2/1/contactin cells than in the other lines listed
above (data not shown). A difference in peak Na+
current could in principle result from a relief of block of expressed channels, an increase in single channel conductance, or a higher density of channels in the surface membrane. As a test of the latter,
we measured 3H-STX binding to these cell lines, and the
results are shown in Figure 3b. Toxin binding for the
Nav1.2/1/contactin cells was approximately fivefold
higher than for Nav1.2/1 or
Nav1.2/contactin. Except for a somewhat higher relative
binding level in Nav1.2/1/2 cells, the
3H-STX binding data agree well with the current density
measurements and argue strongly for increased expression of
Na+ channels in the surface membrane of these cells.
Again, several Nav1.2/1/contactin clones were tested,
with similar results (the graph includes all cells tested).
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Figure 3.
Na+ channel expression in
transfected CHL cells. a, Maximum Na+
current density, plotted as picoamperes per picofaradays of cell
capacitance, for the cell lines indicated along the
abscissa. The number of cells tested for each transfection
paradigm was as follows: Nav1.2, 20;
Nav1.2/contactin, 19; Nav1.2/1, 30;
Nav1.2/1/2, 28; Nav1.2/1/contactin,
43; Nav1.2/2/contactin, 10;
Nav1.2/1/2/contactin, 8. The
Nav1.2/1/contactin result included three different
clones of this transfection combination. b, The percentage
of 3H-STX binding relative to that for
Nav1.2/contactin cells, to the cell lines indicated along
the abscissa. The data for
Nav1.2/1/contactin, Nav1.2/2/contactin,
and Nav1.2/1/2/contactin include measurements on
three different clones. In both a and b, results
for Nav1.2/1/contactin were significantly different from
those for Nav1.2/1 or Nav1.2/contactin cells
(p < 0.005).
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Our work was originally stimulated by the structural homologies noted
previously between contactin and the 2 subunit. However, these
proteins behaved very differently. Substituting contactin for 2 in
the presence of Nav1.2 and 1 increased peak currents significantly. Most interestingly, the combination
Nav1.2/1/contactin produced a very high level of channel
expression, whereas Nav1.2/2/contactin cells had barely
detectable currents and a correspondingly low level of
3H-STX binding. Thus, there was a specific requirement for
1 in the enhancement of Na+ current by contactin.
Cotransfection of 2 with Nav1.2/1 improved cell
surface Na+ channel expression as measured by
3H-STX binding. Furthermore, adding 2 to
Nav1.2/1/contactin cells induced a strong steady-state
inactivation at 70 mV, but surface density was not significantly
affected. Whereas peak currents of Nav1.2/1/contactin
cells were increased by a factor of 3.7 by hyperpolarized holding
potentials, those of Nav1.2/1/2/contactin cells
increased 8.6-fold. Both Na+ currents and
3H-STX binding were undetectable in Nav1.2/2
cells (data not shown). Modulation by 2 was thus dependent on
coexpression of other molecules in the signaling complex.
The results suggest a unique enhancement of functional channel
expression by contactin when present specifically in conjunction with
1. We thus sought evidence for a corresponding biochemical interaction. In the coimmunoprecipitation experiments on rat brain, the
Nav1.2 subunit of Na+ channels is
likely to remain bound to the 1 and 2 subunits during
immunoprecipitation with contactin, because we have used similar
conditions previously to demonstrate association of , 1, and 2
subunits (Malhotra et al., 2001). To identify the
subunit responsible, CHL/1610 cells were transfected with contactin
plus one Na+ channel subunit (Nav1.2,
2, or 1). Cell lysates were prepared and immunoprecipitated with
antibodies to the transfected subunit or nonimmune IgG. Western blots
of the precipitates were probed with anti-contactin antibodies. Neither
anti-Nav1.2 nor anti-2 subunit antibodies
precipitated contactin (Fig. 4, left,
middle). However, 1 did associate
with contactin, as seen in the band above 128 kDa in Figure 4
(right). No contactin was detected in the
immunoprecipitate when nonimmune IgG was substituted for the antibody.
Furthermore, all cell lines were tested by both Northern and Western
blot to ensure that both contactin and the Na+
channel subunit were expressed (data not shown). Thus, three different
approaches (patch clamp of INa,
3H-STX binding, and immunoprecipitation) all point to a
specific interaction between 1 subunits and contactin that results
in an increased surface membrane expression of Na+
channels.
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Figure 4.
Association of contactin with
Na+ channel subunits. Lysates of cells transfected
with contactin plus one Na+ channel subunit were
analyzed by coimmunoprecipitation. In each case, lanes
correspond to beads with nonimmune IgG controls and antibodies, as
marked. Western blots were probed with anti-contactin. Left,
CHL/1610 cells transfected with Nav1.2 and contactin,
immunoprecipitated (IP) with
anti-Na+ channel -subunit antibodies
(NaCh). Middle, Cells transfected with
2 subunits and contactin, immunoprecipitated with anti-2.
Right, Cells transfected with 1 subunits and contactin,
immunoprecipitated with anti-1in antibodies.
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Immunolocalization of contactin and Na+ channels
in PNS axons during remyelination
The spatial and temporal relationship between contactin and
Na+ channels was explored with immunofluorescence in
both the PNS and CNS. In the adult sciatic nerve, 95% of nodes had
contactin label solely within paranodal regions, with none detectable
in the nodal gap occupied by Na+ channels (Fig.
5a). In the remaining 5% of
adult nodes, contactin was also paranodal, but with immunofluorescence
extending at low levels through the region of Na+
channel clustering (Fig. 5b). After a focal intraneural
injection of lysolecithin, myelin is first vesiculated and is then
removed by macrophage phagocytosis, a process that is virtually
complete by 7 d postinjection (dpi) (Hall and Gregson,
1971). Over the second week, Schwann cells proliferate, adhere
to demyelinated axons, and begin the process of remyelination. Schwann
cells that commit to myelin formation and reach an overlapping state of
ensheathment have a sharply altered pattern of protein expression, and,
in particular, begin to express MAG (Martini and Schachner,
1986). Demyelinated zones become covered by short myelin
segments, with new nodes of Ranvier forming at sites that were
previously internodal. The cellular mechanisms involved in
Na+ channel clustering at these new nodes have been
described in detail previously (Dugandzija-Novakovic et al.,
1995; Novakovic et al., 1996). Briefly, axonal
Na+ channel clusters form just outside the tips of
MAG-positive Schwann cell processes and appear to move laterally as
these processes grow. Ultimately, neighboring clusters fuse to form a
node of Ranvier. Immunolocalization suggests that contactin may be
involved in this sequence of events. In fully demyelinated segments,
before Schwann cell adherence, contactin is distributed at low density (Fig. 5c, left), and Na+
channels are likewise diffusely expressed at low levels that can be
detected electrically (Shrager, 1989). At the time of
initial Na+ channel clustering, regions of bright
contactin immunofluorescence appear at the edges of many MAG-positive
Schwann cell processes (Fig. 5c, right). At the initial
stages of remyelination, as new nodes begin to form, contactin extends
into the region of Na+ channel clustering at most
sites. Figure 5d illustrates a single process site, with the
developing paranode at the left and the still-demyelinated
region at the right. Contactin extends through the zone
occupied by Na+ channels. A quantitative analysis
shows that the frequency of occurrence of this overlap is highly
transient, reaching 80% at 9 dpi and then dropping to <10% at 75 dpi
(Fig. 6). There are very few early sites
with contactin exclusively colocalized with Na+
channels and none after 35 dpi. There are likewise only a small number
of early nodes with contactin confined to paranodes (Figs. 5e, 6). Compared with remyelination, contactin is primarily
paranodal during development, and contactin immunofluorescence that
colocalizes with Na+ channels is weak (data not
shown).
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Figure 5.
Immunofluorescence localization of
Na+ channels (green) and contactin
(red) in the PNS. a, b, Adult nodes of Ranvier.
a, At ~95% of sites, contactin was below the level of
detection within the nodal gap occupied by Na+
channels. b, Approximately 5% of adult nodes had a low
level of contactin label colocalizing with Na+
channels. c-e, Demyelinated axons. c,
Left, A demyelinated axon at 9 dpi with contactin
immunofluorescence (red) widely distributed over its
surface. c, Right, Early remyelination: an
adherent Schwann cell labeled with anti-MAG (blue) at 9 dpi.
Clusters of contactin (red) are visible at the Schwann cell
edges. d, A single process cluster of Na+
channels, with the Schwann cell process at the left.
Contactin extends into the region occupied by Na+
channels; 12 dpi. e, A new node of Ranvier at 12 dpi with
contactin primarily paranodal. Scale bars, 10 µm.
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Figure 6.
The frequency of occurrence of three different
patterns of expression of contactin at remyelinating nodes. Sites were
defined as regions containing a cluster of Na+
channels. Filled squares, Contactin only at paranodes.
Filled circles, Contactin exclusively nodal. Filled
triangles, contactin extending from the paranode through the nodal
gap.
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|
Immunolocalization of contactin and Na+ channels
in the CNS
In contrast with the transient and relatively low level of
colocalization in the PNS, contactin and Na+
channels overlapped significantly in CNS axons. Figure
7A illustrates axons from
large cortical cells of an adult rat brain as they enter white matter.
A number of nodes of Ranvier are visible (a), stained with
the anti-Na+ channel antibody, and virtually all of
these are also immunoreactive for contactin (b, c). Rat
optic nerve fibers are shown in Figure 7B. Double-labeling
for Caspr (a) shows that contactin is both paranodal
and within the nodal gap (b, c). Eighty-four
percent of nodal Na+ channel clusters were
colocalized with contactin (d-f). At postnatal day
13, nodes in the optic nerve are at an early stage of
development, and there are ~25% of the adult number of
Na+ channel clusters visible (Rasband et al.,
1999). Contactin overlaps with Na+ channels
at these sites but is also visible in numerous small puncta (Fig.
7C, a-c). These foci of immunoreactivity are
visible over axonal regions, which are delineated by anti-neurofilament antibodies (d-f) but are not seen in the intervening
spaces. These gaps are presumably occupied by glial cell bodies,
because they are stained in discrete loci by an antibody to -COP, a
Golgi apparatus coat protein (data not shown).
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Figure 7.
Colocalization of contactin and
Na+ channels in the CNS. Left column,
Immunolabel as indicated in each panel (green);
middle column, contactin (red); right
column, merge. A, Cryosectioned myelinated axons from
large cortical cells in adult rat brain. Numerous nodes of Ranvier are
visible and are stained for Na+ channels and
contactin. Scale bar, 10 µm. B, Adult rat optic nerve,
double-labeled for Caspr/contactin (a-c) and
Na+ channels/contactin (d-f).
Scale bars, 5 µm. C, Postnatal day 13 rat optic
nerve cryosections double-labeled for Na+
channels/contactin (a-c) and neurofilaments/contactin
(d-f). Scale bars, 10 µm.
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DISCUSSION |
We used a wide variety of experimental approaches, including
biochemical association, electrophysiology, toxin binding, and immunocytochemistry to investigate a possible interaction of contactin with Na+ channels that has functional significance.
Measurements were made both on cell lines engineered to express
different combinations of Na+ channel subunits and
contactin and on CNS and PNS tissue. In the cotransfection studies, we
found that peak inward Na+ currents were
significantly higher with the combination
Nav1.2/1/contactin than any other group tested. What
event is responsible for this result? An increase in peak current would
of course result from an increased Na+ channel
density. There are, however, several other mechanisms that could also
produce higher peak currents with contactin but involve no change in
channel density: a "blocking" component removed by contactin, an
increase in the single channel conductance, or a change in the level of
steady-state inactivation. The last of these is essentially ruled out
by the experiment varying holding potential. When this voltage was
changed from 70 mV to the level required for a maximum response, the
peak current in Nav1.2/1/contactin cells increased
3.7-fold. This increase is virtually the same as that of the other cell
types, indicating no unusual alteration in inactivation with contactin.
Most importantly, 3H-STX binding paralleled the current
density measurements very closely, arguing strongly for an increased
surface density of Na+ channels as the basis for the
higher currents. The toxin and electrical measurements are
complimentary because STX binding alone could in principle include
receptor sites on nonfunctional channels. The combined results suggest
that contactin increased significantly the density of functional
Na+ channels in the surface membrane and that the
1 subunit was essential for this higher expression.
A possible biochemical link was explored with coimmunoprecipitation.
Contactin and Na+ channels could be reciprocally
immunoprecipitated from a rat brain lysate, indicating both a possible
association between them and also extending the result to the CNS. The
evidence suggested that only a fraction of the total contactin in the
brain is associated with Na+ channels. This is
perhaps not surprising given the many functions already known for
contactin, as noted below. The immunoprecipitation experiment left open
the possibility that the interaction was indirect and also did not
identify which Na+ channel subunit is involved. We
therefore examined CHL cells transfected with contactin plus just a
single subunit to better define the complex and also to eliminate many
possible neuronal intermediates. This experiment demonstrated that only
1 antibodies could coprecipitate contactin. The biochemical
association thus provided strong support for the results of both
electrophysiology and toxin binding that pointed to the necessity for
1 for enhancement of Na+ channel expression.
In neurons, Na+ channels are expressed at high
density at axon initial segments and nodes of Ranvier. In the CNS, we
found that contactin was colocalized with Na+
channels within the nodal gap in both the brain and optic nerve, and
this association may form the basis for the copurification observed. We
showed further that contactin was present at the node at 2 weeks
postnatal, a time of active Na+ channel clustering
in the optic nerve (Rasband et al., 1999). Thus, within
the CNS, we have both biochemical and morphological evidence for an
interaction between contactin and Na+ channels. In
the PNS, although contactin was only rarely seen at the node in the
adult, it was transiently present at low levels early in development
and, more prominently, during remyelination. As axons are remyelinated,
the nodal presence of contactin is highest just as new
Na+ channel clusters begin to form (9 dpi) and falls
rapidly as the latter coalesce and become more focal.
Combining the transfection experiments that demonstrated that contactin
can specifically enhance surface expression of functional Na+ channels with the biochemical and morphological
association seen in the CNS suggests a significant role for contactin
in establishing neuronal Na+ channel distributions.
The results do not argue that contactin has a direct role in the
glial-dependent Na+ channel clustering that
accompanies formation of nodes of Ranvier. This work suggests rather
that contactin may be important for the increased surface expression
that would be required for subsequent glial-directed clustering. There
are significant differences between nodes of Ranvier in the PNS and
CNS, including the possibility that Na+ channel
clustering is contact dependent in the former but secretion dependent
in the latter (Kaplan et al., 1997). The role of
contactin at these two structures may thus also differ, with a unique
requirement for stability of Na+ channel clusters at
mature nodes in the CNS. In the PNS, participation seems to be limited
to a more transient association with Na+ channels.
Recently, we have reported also evidence for participation of subunits in cell adhesion through interaction with extracellular matrix
components and the cytoskeleton (Xiao et al., 1999;
Malhotra et al., 2000). Using Drosophila S2
cells, it was shown that homophilic adhesion of 1 or 2 subunits
in the presence or absence of Nav1.2 subunits results
in cellular aggregation and recruitment of ankyrin to points of
cell-cell contact. subunit mutant constructs that lack the
intracellular domains cause cellular aggregation but are incapable of
recruiting ankyrin. In addition, 1 or 2 subunits and ankyrin G
can be coimmunoprecipitated from solubilized rat brain membranes,
suggesting that they may participate in a signaling complex, although
additional investigation will be required to demonstrate a direct interaction.
Contactin thus appears to have multiple roles in axonal development and
repair. As a GPI-anchored protein, it may be targeted to the axon
through its incorporation in detergent-insoluble
sphingolipid-cholesterol rafts (Olive et al., 1995;
Ledesma et al., 1998), and it could require binding
partners to effect intracellular signaling. Through an association with
an -1 complex, it could promote surface expression of functional
Na+ channels in the axolemma, leading ultimately to
high-density clusters at nodes of Ranvier. It is important in this
regard to note that contactin also binds NrCAM and neurofascin,
other membrane glycoproteins that are expressed at nodes and that have
been implicated in Na+ channel clustering
(Grumet, 1997; Lambert et al., 1997;
Volkmer et al., 1998). Does contactin play a primary
role in targeting Na+ channels to nodes in the CNS?
On the one hand, its distribution in both nodes and paranodes would
argue against this idea. However, it has been shown recently that one
isoform of contactin associates closely with Caspr and colocalizes in
paranodes, whereas another isoform, differing in glycosylation, is
independent of Caspr and extends into the nodal gap of CNS axons
(Rios et al., 2000), leaving open the possibility of
some regional specificity. Alternatively, contactin may serve as a
cofactor to promote high levels of functional Na+
channels, which then are targeted to nodes by additional mechanisms. Contactin is required for surface expression of Caspr in
vitro (Faivre-Sarrailh et al., 2000), and, through
this association, it may help to stabilize the axoglial junctions as
paranodes mature. In mice with contactin genetically deleted, axonal
and dendritic guidance and interactions are disrupted in the
cerebellum, and paranodes are abnormal (Berglund et al., 1999,
2000). Finally, since oligodendrocytes also express this
molecule (Koch et al., 1997; Kramer et al.,
1999), interactions with Na+ channels may be
cis or trans, and contactin may thus mediate in
part the glial-neuronal communication involved in ion channel organization.
| |
FOOTNOTES |
Received May 24, 2001; revised June 29, 2001; accepted July 6, 2001.
This work was supported by National Institutes of Health Grants
NS17965, DK34933, MH59980, and GM07767 and National Science Foundation
Grant IBN 9734462. We thank Deana Amico and Matthew Koopmann for expert
technical assistance.
K.K.-N., J.D.M. and D.P.M. contributed equally to this work.
Correspondence should be addressed either to Dr. Lori L. Isom,
Department of Pharmacology, University of Michigan Medical School,
1301E MSRB III, Ann Arbor, MI 48109-0632 or to Dr. Peter Shrager,
Department of Neurobiology and Anatomy, Box 603, University of
Rochester Medical Center, 601 Elmwood Avenue, Rochester, NY 14642. E-mail: lisom{at}umich.edu or pshr{at}mail.rochester.edu.
| |
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TOP
ABSTRACT
INTRODUCTION
