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The Journal of Neuroscience, November 15, 2000, 20(22):8354-8364
Contactin-Associated Protein (Caspr) and Contactin Form a Complex
That Is Targeted to the Paranodal Junctions during Myelination
Jose C.
Rios1,
Carmen
V.
Melendez-Vasquez1,
Steven
Einheber1,
Marc
Lustig2,
Martin
Grumet2,
John
Hemperly5,
Elior
Peles6, and
James L.
Salzer1, 3, 4
Departments of 1 Cell Biology,
2 Pharmacology, 3 Neurology, and the
4 Kaplan Cancer Center, New York University School of
Medicine, New York, New York 10016, 5 BD Technologies,
Research Triangle Park, North Carolina 27709, and
6 Department of Molecular Cell Biology, The Weizmann
Institute of Science, Rehovot 76100, Israel
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ABSTRACT |
Specialized paranodal junctions form between the axon and the
closely apposed paranodal loops of myelinating glia. They are interposed between sodium channels at the nodes of Ranvier and potassium channels in the juxtaparanodal regions; their precise function and molecular composition have been elusive. We previously reported that Caspr (contactin-associated protein) is a major axonal
constituent of these junctions (Einheber et al., 1997
). We now report
that contactin colocalizes and forms a cis complex with
Caspr in the paranodes and juxtamesaxon. These proteins coextract and
coprecipitate from neurons, myelinating cultures, and myelin preparations enriched in junctional markers; they fractionate on
sucrose gradients as a high-molecular-weight complex, suggesting that
other proteins may also be associated with this complex. Neurons
express two contactin isoforms that differ in their extent of
glycosylation: a lower-molecular-weight phosphatidylinositol phospholipase C (PI-PLC)-resistant form is associated specifically with
Caspr in the paranodes, whereas a higher-molecular-weight form of
contactin, not associated with Caspr, is present in central nodes of
Ranvier. These results suggest that the targeting of contactin to
different axonal domains may be determined, in part, via its
association with Caspr. Treatment of myelinating cocultures of Schwann
cells and neurons with RPTP
-Fc, a soluble construct containing the
carbonic anhydrase domain of the receptor protein tyrosine phosphatase
(RPTP), a potential glial receptor for contactin, blocks the
localization of the Caspr/contactin complex to the paranodes. These
results strongly suggest that a preformed complex of Caspr and
contactin is targeted to the paranodal junctions via extracellular
interactions with myelinating glia.
Key words:
myelin; axons; Caspr; contactin; nodes of Ranvier; paranode
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INTRODUCTION |
Myelinated fibers are organized into
distinct domains: the internode, the juxtaparanodal and paranodal
regions, and the node of Ranvier (Salzer, 1997). This organization,
which is critical for appropriate saltatory conduction, results from
poorly understood interactions between axons and Schwann cells in the
PNS and oligodendrocytes in the CNS. Each of these domains has a
distinct molecular composition and physiological role (Arroyo and
Scherer, 2000; Peles and Salzer, 2000). Thus, high concentrations of
voltage-gated sodium channels and delayed rectifier potassium channels
are found in the nodal and juxtaparanodal regions, respectively.
Specialized paranodal junctions (PNJs), which form between the axolemma
and the closely apposed paranodal loops of myelinating glia (Peters et
al., 1991), are interposed between these channel domains. These
junctions have been proposed to anchor myelin loops to the axon, form a
partial diffusion barrier into the periaxonal space, and demarcate
axonal domains by limiting the lateral diffusion of membrane components
(Rosenbluth, 1995). They also represent a potential site for
bidirectional signaling between axons and myelinating glia. Evidence
for a critical role of the PNJs in organizing these domains has come
from studies of galacto-cerebroside-deficient mice (Coetzee et al.,
1996; Bosio et al., 1998). In the PNS of these mice, the transverse
bands, which are the hallmark of these junctions, are missing (Dupree
et al., 1999). Of note, the distribution of
K+ channels was perturbed significantly,
and the strict separation between Na+ and
K+ channels that is a prominent feature of
normal axons was frequently absent.
The first major component of these junctions to be identified was the
contactin-associated protein (Caspr), also termed paranodin (Einheber
et al., 1997; Menegoz et al., 1997). Caspr was isolated originally on
the basis of its copurification with contactin when the carbonic
anhydrase domain of the receptor protein tyrosine phosphatase (RPTP) was used as an affinity ligand (Peles et al., 1997). Caspr is
a neuronal transmembrane protein with an Mr of 190 kDa that contains
extracellular neurexin-like repeats and potential binding sites for SH3
domains and band 4.1 proteins in its cytoplasmic region (Peles et al.,
1997). It is expressed diffusely on unmyelinated axons but becomes
localized to the paranodal junctions shortly after the onset of
myelination (Einheber et al., 1997). Contactin is a
glycosylphosphatidyl inositol (GPI)-anchored member of the
immunoglobulin gene superfamily (Ranscht, 1988; Brümmendorf et
al., 1989; Gennarini et al., 1989), which promotes neurite outgrowth
and fasciculation and possibly synapse formation and maintenance
(Faivre-Sarrailh and Rougon, 1997; Berglund et al., 1999). It is
expressed by most neurons in the PNS and CNS as well as by mammalian
oligodendrocytes (Einheber et al., 1997; Koch et al., 1997), but not by
Schwann cells (Einheber et al., 1997). Despite evidence that Caspr and
contactin interact laterally in the plasma membrane of neuronal cell
lines (Peles et al., 1997), we were unable to detect contactin in the
paranodes in our previous studies (Einheber et al., 1997).
Using new reagents, we now report that contactin indeed colocalizes and
is targeted with Caspr to the paranodes and the juxtamesaxonal spiral.
We also show that contactin and Caspr interact laterally, i.e., in
cis, and are likely to be targeted to these axonal domains as a complex. Finally, treatment of myelinating cocultures with a
soluble RPTP-Fc construct, which binds tightly to contactin, blocks
the redistribution of Caspr and contactin to the paranodes, suggesting
that extracellular interactions regulate their localization.
Portions of this work have appeared in abstract form (Melendez-Vasquez
et al., 1999; Rios et al., 1999).
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MATERIALS AND METHODS |
Fc fusion proteins. Two Fc fusion proteins were used
in these studies. One contained the carbonic anhydrase domain of
RPTP fused to the hinge region of human IgG1-Fc (C-Fc; Peles et
al., 1997); the other consisted of the extracellular domain of human contactin/F3 also fused to the same Fc region (contactin-Fc; Peles et
al., 1995). Stably transfected HEK 293 cells secreting either C-Fc
or contactin-Fc were maintained on media containing DME (Whittaker
Bioproducts, Walkersville, MD), 4% Ultra-Low IgG fetal bovine serum
(FBS; Life Technologies, Gaithersburg, MD), and 2 mM
glutamine. Conditioned media were collected once a week and alkalinized
by adding 1 M HEPES buffer (Life Technologies) at 10%
volume. Fc fusion proteins were collected by using a protein A-agarose
column (Roche Molecular Biochemicals, Indianapolis, IN). The column was
washed sequentially with 6× Dulbecco's PBS (dPBS; Life Technologies)
plus 0.2% Triton X-100 (Sigma, St. Louis, MO), followed by 6× dPBS
and 1× dPBS. The proteins were eluted off the column with 100 mM glycine buffer, pH 2.8; individual fractions were
neutralized with 2 M HEPES, pH 8.5, at 5% volume, and the
protein levels were assessed by the Bradford method (Bio-Rad, Hercules,
CA). Fractions containing Fc proteins were pooled and dialyzed against
dPBS; protein quantitation was performed with the BCA Protein Assay
(Pierce, Rockford, IL).
Tissue culture methods. Primary rat Schwann cell and dorsal
root ganglion (DRG) neuron cultures and myelinating Schwann
cell-neuron cocultures were established as described previously
(Einheber et al., 1997) with minor modifications. Embryonic day 16-17
(E16-E17) rat DRGs were explanted directly into culture or were
trypsinized first (Life Technologies) and dissociated by trituration
before being plated onto 12 mm glass coverslips coated with collagen (Biomedical Technologies, Stoughton, MA). Cultures were maintained in
standard neuronal media, which consisted of MEM (Life Technologies) supplemented with 10% FBS, 2 mM glutamine, 0.4% glucose
(Sigma), and 50 ng/ml 2.5S nerve growth factor (NGF; Bioproducts for
Science, Indianapolis, IN). During the first 2.5 weeks the cultures
were treated with 5-fluorodeoxyuridine and uridine at
10
5
M (Sigma) that were added to the standard neuronal media in
alternate feedings to eliminate non-neuronal cells.
Schwann cell/neuronal cocultures were prepared by seeding purified DRG
explants or dissociated cultures with 200,000 Schwann cells per
coverslip in standard neuronal media. The next day the cocultures were
fed with N2 media consisting of 5 mg/ml insulin (Sigma), 10 mg/ml
transferrin (Jackson ImmunoResearch Laboratories, West Grove, PA), 20 nM progesterone (Sigma), 100 µM putrescine (Sigma), 30 nM selenium (Sigma), and 2 mM
glutamine in a 1:1 mixture of DME and Ham's F-12 (Life Technologies)
supplemented with 2.5S NGF. They were maintained in N2 for 3-4 d so
that the Schwann cells could populate the neurites. To initiate basal
lamina formation and myelination, the cocultures were fed standard
neuronal media supplemented with 50 µg/ml ascorbic acid (Sigma). For
perturbation studies C-Fc or human IgG (Jackson ImmunoResearch
Laboratories; both at 25 µg/ml or 100 µg/ml) was added to the
myelinating media. After 15 or 21 d of treatment the cocultures
were fixed with 4% paraformaldehyde and were processed for immunofluorescence.
Preparation of teased sciatic nerves and optic nerve sections.
Sciatic nerves were removed from Sprague Dawley rats (Taconic Farms, Germantown, NY) of specified ages and fixed in dPBS with 4%
paraformaldehyde (Fisher Scientific, Springfield, NJ) for 1.5 hr for
the nerves from postnatal day 0-4 rat pups and for 4 hr for the nerves
from adults. The nerves were stored in dPBS at 4°C until teased.
Using fine needles, we teased the individual fibers of the sciatic
nerve while they were in ice-cold dPBS. Teased sciatic nerve fibers
(TSNs) then were mounted on glass slides and dried overnight at room
temperature. The slides were stored at 
80°C until they were stained
for immunofluorescence. Optic nerves were dissected out and fixed in
4% paraformaldehyde (Fisher Scientific) in dPBS for 1.5 hr. The nerves
were stored in dPBS and then cryoprotected with 30% sucrose (Sigma).
Nerves were frozen with crushed dry ice and stored at 80°C. Tissue
was mounted with Tissue-Tek OCT (VWR Scientific Products, New York, NY)
for cryostat sectioning. Tissue was sectioned at 10 µm on a Leica
CM1900 cryostat with a chamber temperature of 24°C and stage
temperature of 26°C. Sections were stored at 80°C until they
were stained for immunofluorescence.
Antibodies and immunofluorescence. For many of these studies
we used an affinity-purified rabbit polyclonal antibody generated against human contactin/F3 (Reid et al., 1994). Rabbit polyclonal antibodies to Caspr (Peles et al., 1997), myelin-associated
glycoprotein (MAG; Pedraza et al., 1990), myelin basic protein (MBP;
gift of D. Colman, Mount Sinai Medical Center New York, NY), and L1
(Friedlander et al., 1994) and a chicken antibody to ankyrinG (gift of
S. Lambert, University of Massachusetts, Worcester, MA) also were used.
We also generated a rabbit polyclonal antibody to contactin by
immunizing with the contactin-Fc fusion protein described above. The
anti-MBP monoclonal antibody SMI 94 (Sternberger Monoclonals,
Baltimore, MD) was used to stain myelin segments. Goat secondary
antibodies to rabbit or human IgG conjugated to rhodamine or FITC
and goat anti-mouse antibodies conjugated to FITC were purchased from
Jackson ImmunoResearch Laboratories; goat secondary antibodies to
rabbit or human IgG conjugated to Alexa 594 and to human IgG conjugated to Alexa 488 were purchased from Molecular Probes (Eugene, OR).
Fixed tissue samples (TSNs, optic nerve sections, cocultures, and
capped DRG neurons) were permeabilized with acetone at 20°C, washed
with dPBS, and blocked for 1 hr at room temperature in a blocking
solution consisting of dPBS, 5% BSA, 1% normal goat serum, and 0.2%
Triton X-100 (Sigma). Primary antibodies diluted in blocking solution
were added and left overnight in a humidifying chamber at 4°C. After
being washed several times with dPBS plus 0.2% Triton X-100, the
tissue was incubated with corresponding secondary antibodies at a
dilution of 1:100 in blocking solution for 1 hr at room temperature.
Then the tissue was washed several times with dPBS, washed once with
water, and mounted in Citifluor (Ted Pella, Redding, CA) containing
Hoechst nuclear stain. The tissue was examined by epifluorescence on
either a Zeiss Axiophot microscope or on a Zeiss LSM 510 confocal microscope.
Cocapping studies. For analysis of protein association by
cocapping, DRG neurons were rinsed with dPBS and then incubated with
conditioned media collected from C-Fc-secreting HEK 293 cells
(Peles et al., 1995) for 1 hr at 4°C. Cultures were washed with dPBS
for 5 min at 4°C and incubated with Alexa 488-conjugated goat
anti-human IgG for 1 hr at 4°C. Cultures were washed with dPBS and
either were fixed directly or were incubated in standard media for an
additional 6 hr at 37°C and fixed. Then the cultures were stained for
contactin, Caspr, or L1 as described above.
Isolation of myelin fractions. Myelin was prepared from
frozen adult rat brains (Pel-Freez Biologicals, Rogers, AR) according to the method of Norton and Poduslo (1973) with minor modifications. Briefly, five rat brains were homogenized in 170 ml of 0.85 M sucrose in 10 mM Tris buffer, pH 7.4, containing 2 mM EDTA and 1 mM PMSF. The
homogenate was transferred to six Nalgene centrifuge tubes (Nalge Nunc,
Rochester, NY) and layered with 8 ml of 0.25 M sucrose. The
homogenate was centrifuged overnight in a SW28 Beckman rotor (Beckman
Instruments, Palo Alto, CA) at 22,500 rpm. The crude myelin at the
0.25/0.85 M interface was collected and osmotically shocked
by washing with 10 vol of distilled water. Myelin subfractions were
obtained by subjecting the initial myelin preparation to a second
discontinuous sucrose gradient consisting of 15 ml of 0.62 M sucrose layered over 15 ml of 0.70 M sucrose (Matthieu et al., 1973). After centrifugation at 67,000 × g for 30-45 min, three fractions were collected: material
less dense than 0.62 M sucrose (light myelin),
material within the 0.62-0.70 M layer (medium
myelin), and the pellet (heavy myelin). The starting myelin preparation
and the myelin subfractions were washed with Tris-EDTA buffer and kept
at 80°C until required.
Myelin was prepared from the PNS by grinding 25 frozen rat sciatic
nerves (Pel-Freez Biologicals) in a ceramic mortar cooled with liquid
nitrogen (Greenfield et al., 1973). The nerve powder was collected and
homogenized in 10 ml of 0.32 M sucrose in Tris-EDTA buffer. The homogenate was filtered through a 200 µm nylon mesh to
remove the bulk of the collagen and layered at the top of a centrifuge
tube containing 0.9 M sucrose. Tubes were spun overnight at
22,500 rpm in a SW28 rotor (Beckman Instruments), and the myelin migrating at the 0.32/0.9 M sucrose interface was
collected, washed, and kept at 80°C until further use.
Detergent solubilization. Unfractionated myelin and myelin
subfractions (1 mg total protein) were extracted with 1 ml of a detergent solution prepared in Tris buffer (10 mM, pH 7.4),
containing 10 mM EDTA, 1 mM PMSF, 10 µg/ml
aprotinin, and 20 µM leupeptin with or without 500 mM NaCl. The following detergents and concentrations were
used: 1% Triton X-100, 60 mM octyl glucoside, 1% SDS
(Sigma), 0.9% Zwittergent 3-14 (ZW 3-14; Calbiochem, La Jolla, CA),
and 2% sucrose monolaurate (Roche Molecular Biochemicals). Samples were incubated for 1 hr at 4°C with constant agitation, except for
SDS extractions that were performed at room temperature for 30 min
only. Detergent-soluble (supernatants) and insoluble fractions (pellets) were separated by centrifugation at 12,000 × g for 10 min in a Marathon 13K/M microcentrifuge (Fisher
Scientific) and analyzed by Western blotting. Detergent extracts also
were prepared from primary cultures of DRG neurons and myelinating
cocultures following the protocol described above.
Sucrose gradient analysis. Supernatants from detergent
extracts were subjected to sucrose density gradient centrifugation to
estimate the molecular size of solubilized Caspr and contactin (Martin
and Ames, 1961). Briefly, 0.25-1 ml of extracts were layered on top of
11 ml of a continuous 10-45% sucrose gradient made up in Tris-EDTA
buffer, pH 7.4 (10 mM Tris, 10 mM EDTA).
Samples were centrifuged for 20 hr at 35,000 rpm in a Beckman SW41
rotor (Beckman Instruments). Fractions of 1 ml were harvested from the top, and their density was determined by measurement of the refractive index. The protein composition of each fraction was analyzed by SDS-PAGE and Western blotting. Molecular weight standards (Sigma) consisting of bovine thyroglobulin (669 kDa), horse apoferritin (443 kDa), and bovine gamma globulin (150 kDa) were analyzed in parallel.
Metabolic labeling and immunoprecipitation. DRG neurons and
myelinating cocultures were rinsed with methionine-free DMEM
(Life Technologies). Cultures were labeled for 16-18 hr with DMEM
containing 250 µCi/ml [35S]methionine
(Trans35S-Label, ICN Biomedicals, Costa
Mesa, CA). At the end of the labeling period the radioactive medium was
removed, and the cultures were chased for 2 hr in complete DMEM (Life
Technologies). Cultures were washed three times with PBS and extracted
with detergents as described above. One set of neuron cultures was
treated with 1 U/ml of phosphatidylinositol phospholipase C (PI-PLC;
Sigma) for 1 hr at 37°C before detergent extraction and
immunoprecipitation. Cell detergent extracts were diluted two to four
times with Tris-EDTA buffer, pH 7.4 (10 mM Tris, 10 mM EDTA) and precleared for 1 hr with protein-A agarose.
For SDS extracts, the dilution buffer included 2% Triton X-100.
Extracts then were incubated for 2 hr at 4°C with Caspr, contactin,
or preimmune serum or with protein A-agarose beads coupled to
RPTPC-Fc fusion protein. For Caspr, contactin, and preimmune serum
immunoprecipitations, protein-A beads were added after antibody
incubation. Beads were collected by centrifugation and washed four to
five times with Tris-EDTA buffer containing the detergent used for
solubilization. After the last wash, consisting only of Tris-EDTA
buffer, the beads were boiled for 3 min in SDS sample buffer.
Immunoprecipitates were fractionated by SDS-PAGE and analyzed by
autoradiography with a PhosphorImager (Molecular Dynamics, Sunnyvale, CA).
In other studies, ZW 3-14 extracts of heavy myelin fractions were
incubated for 2 hr with RPTPC-Fc fusion protein coupled to
CNBr-Sepharose (Amersham Pharmacia Biotech, Piscataway, NJ). Beads were
washed four to five times with 0.09% ZW 3-14 in Tris-EDTA buffer, pH
7.4 (10 mM Tris, 10 mM EDTA) and boiled in SDS
sample buffer. Precipitates from heavy myelin were separated by
SDS-PAGE and analyzed by silver staining (Silver SNAP Stain, Pierce)
and Western blotting. Blots were developed using the SuperSignal
chemiluminescent substrate (Pierce).
Surface biotinylation and enzymatic deglycosylation.
Cultures of DRG neurons were washed two times, for 5 min each,
with ice-cold PBS and then biotinylated with 0.5 mg/ml of
sulfo-NHS-LC-biotin (Pierce) for 30 min at 4°C. Cells were washed two
times for 10 min with Leibovitz's L-15 medium (Life Technologies) to
quench unreacted biotin and then with ice-cold PBS. Biotinylated
cultures were lysed in 0.9% ZW 3-14 and subjected to
immunoprecipitation with anti-contactin antibodies as described above.
Contactin immunoprecipitates were denatured by boiling in 0.5% SDS and
1% -mercaptoethanol for 10 min and then treated with 12,500 U/ml
PNGase F (New England Biolabs, Beverly, MA) for 1 hr at 37°C in
buffer containing 1% NP-40. The reaction was stopped by adding
SDS-PAGE sample buffer. Immunoprecipitates treated in parallel without
enzyme served as a control. Samples were separated by SDS-PAGE and
analyzed by Western blotting. Blots were developed using
streptavidin-peroxidase (Jackson ImmunoResearch Laboratories) and the
SuperSignal chemiluminescent substrate (Pierce).
Analysis of C-Fc-treated cultures. The distribution of
Caspr in control and C-Fc-treated cultures (25 and 100 µg/ml) was determined in both explant and dissociated neuron-Schwann cell cocultures; similar results were observed in each type of culture. Quantitation of three separate experiments was performed by counting from photomicrographs of high power (400×) fields or, in the case of
explant cultures, quantifying the Caspr-staining pattern of MBP-positive segments throughout the entire coverslip. Over 500 paranodes were analyzed for each C-Fc concentration.
| |
RESULTS |
Colocalization of contactin and Caspr at the paranode in
vivo and in vitro
In previous studies we reported that, although Caspr and contactin
can be detected by Western blot analysis after myelination in
vivo and in vitro, only Caspr was detected at the
paranodes (Einheber et al., 1997). We have reexamined the distribution
of contactin in myelinated axons by using additional reagents: rabbit polyclonal antibodies, generated against affinity-purified contactin (Reid et al., 1994) or contactin-Fc, and the RPTPC-Fc (C-Fc) fusion protein (Peles et al., 1995).
Staining of adult teased sciatic nerves (TSNs) with these reagents
demonstrated abundant expression of contactin in the paranodes (Fig.
1). C-Fc labeled the paranodes and a
thin spiral extending into the internode (Fig. 1a,a').
Double staining with MAG antibodies (data not shown) confirmed that
this staining apposes the Schwann cell mesaxon; consequently, we refer
to this domain as the juxtamesaxon. An identical staining pattern in
the paranodes and juxtamesaxon also was seen with polyclonal antibodies
raised against affinity-purified contactin (Fig. 1b') or
contactin-Fc (data not shown). Staining with C-Fc was specific for
contactin because it could be blocked by preincubating with
contactin-Fc (Cn-Fc; Fig. 1b,f). Caspr
and contactin precisely colocalize in the paranodes and the
juxtamesaxon, as illustrated in the merged images of TSNs
double-labeled with anti-Caspr antibodies and C-Fc (Fig.
1e,a'). The distribution of contactin in
myelinating fibers in the DRG neuron/Schwann cell cocultures was
similar to that in the TSNs, with significant levels in the paranodes
and minimal expression in the internodes (data not shown). Labeling of
the juxtamesaxon was infrequent in the cocultures.
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Figure 1.
Contactin expression in the paranodes and
juxtamesaxonal spiral. Top Panels, Teased fibers from
adult rat sciatic nerves were stained with C-Fc (fluorescein
secondary) and with antibodies to Caspr (rhodamine secondary) either
directly (a, c, e) or after preincubation of these
reagents with contactin-Fc (b, d, f). C-Fc
(a) and Caspr antibodies
(c) both stain the paranodes and colocalize in
the merged image (e). The staining of C-Fc is
specific for contactin because preincubation with contactin-Fc
eliminated all staining (b) without affecting
Caspr labeling (d); the merged image is shown in
f. Bottom panels, Higher magnification of
the paranodal region shows colocalization of contactin, stained with
C-Fc and Caspr in the paranodes and in the juxtamesaxonal spiral in
a merged confocal image (a'). Staining with an
affinity-purified antibody against contactin (b')
similarly demonstrates paranodal and juxtamesaxonal staining. Scale
bars: a-f, 20 µm; a',
b', 10 µm.
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Next, we examined contactin distribution in CNS myelinated fibers (Fig.
2). Frozen sections of optic nerve were
stained with C-Fc (Fig. 2a) and antibodies to Caspr
(Fig. 2c), followed by fluorescein- and rhodamine-conjugated
secondary antibodies, respectively. As evident by confocal microscopy,
both reagents exclusively stained the paranodes (shown merged in Fig.
2e). Again, the C-Fc staining was specific for
contactin, because it could be blocked completely by preincubation with
contactin-Fc (data not shown). In comparison to the PNS, CNS axons
were of smaller diameter, and their nodal and paranodal regions were
longer relative to their diameter. Antibodies to contactin itself also
stained the paranodes (Fig. 2b). Of note, and in contrast to
the PNS, this staining extended through the nodal region of many optic
nerve fibers, as identified with antibodies to ankyrinG. Overlap of
contactin and ankyrin is evident at several nodes (indicated by
arrowheads in Fig. 2b,f). In addition,
staining with this contactin antibody was present diffusely around some
optic nerve fibers, possibly representing oligodendrocyte plasma
membranes (data not shown). These results suggest that C-Fc
preferentially recognizes the Caspr/contactin complex (see below),
which is exclusively present in the paranodes, whereas the
anti-contactin antibody recognizes contactin in the nodes, paranodes,
and possibly on oligodendrocyte membranes.
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Figure 2.
Contactin is localized in the paranodes and nodes
in the optic nerve. Staining of contactin with C-Fc
(a) and an anti-Caspr antibody
(c) demonstrated specific colocalization of these
proteins at the paranodes (merged in e). Staining with
an affinity-purified anti-contactin antibody (b)
demonstrates that contactin in the paranodes frequently extends through
the nodes of Ranvier; an antibody to ankyrinG (d)
identifies the nodes in the same field. In the merged images
(f), contactin that is colocalized with ankyrinG
at the node appears yellow; nodes in which contactin is
readily visible are indicated by the white arrowheads.
Scale bar, 5 µm.
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Developmental time course of contactin and Caspr accumulation at
the paranodes
To determine whether contactin and Caspr accumulate in the
paranodal region simultaneously, we analyzed the expression of these
proteins in sciatic nerves of rats at postnatal day 0 (P0), P2, and P4.
We compared staining for Caspr and contactin with that of MBP, a marker
of compact myelin (Fig. 3). At P0, only a
few MBP-positive myelin segments were present, and staining for both
contactin and Caspr was diffuse even at the prospective paranodes
adjacent to these MBP-positive segments. By P2, the number of
MBP-positive segments had increased significantly, and contactin and
Caspr were both present in many of the associated paranodes. The Caspr
staining was typically more intense at this stage, possibly reflecting
differences in the affinity of these antibodies. Both proteins were
most highly concentrated adjacent to the nodes, consistent with the
pattern of paranodal junction formation, which begins closest to the
node and progresses inward (Tao-Cheng and Rosenbluth, 1983). In
unmyelinated axons, Caspr and contactin remained diffuse. By P4, myelin
segments were abundant, and essentially every paranode was strongly
positive for both contactin and Caspr. Interestingly, the levels of
both proteins were reduced significantly in the corresponding
internodes, consistent with findings in the myelinating cocultures.
These results indicate that contactin and Caspr accumulate in the
paranodes shortly after the onset of myelination and suggest they may
be targeted to the paranodes as a complex.
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Figure 3.
Time course of contactin and Caspr accumulation in
the paranodes. Sciatic nerves were removed on P0, P2, and P4, teased,
and stained for MBP (fluorescein) and either contactin
(Cn) or Caspr (Cs; rhodamine). At P0, few
myelin segments have formed, and contactin and Caspr are distributed
diffusely on axons. At P2, the number of myelin segments and nodes of
Ranvier (white arrowheads) increased significantly, and
the first clusters of contactin and Caspr at the paranodes are
apparent; the level of contactin at the paranode appears to be less
than that of Caspr. By P4, substantial numbers of myelin segments have
formed, and contactin and Caspr are highly concentrated in the
paranodes. Scale bar, 10 µm.
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Caspr and contactin cofractionate and coextract from an enriched
preparation of paranodal junctions
We next examined whether Caspr and contactin interact laterally,
i.e., in cis, in the paranodes. Because Caspr and contactin are also present at significant levels in gray matter (Einheber et al.,
1997; Menegoz et al., 1997), in addition to their localization in the
paranodal junctions, we first prepared membrane fractions enriched in
these junctions. To this end we prepared crude myelin fractions from
rat brain, which are known to contain axolemma, trapped axoplasm, and
periaxonal glial membranes in addition to compact myelin (Norton and
Cammer, 1984). We separated these preparations into light (enriched in
compact myelin), medium, and heavy (enriched in axolemma and glial
membranes) fractions by sucrose gradient centrifugation (Matthieu et
al., 1973). Finally, we determined the amount of Caspr, contactin, and
MBP in each fraction. Results, shown in Figure
4A, demonstrate that
Caspr and contactin are enriched substantially in the heavy myelin
fraction; there was a similar enrichment of MAG in these fractions
(data not shown). MBP demonstrates a more uniform distribution; in some
studies MBP was mainly present in the light fractions. These results
indicate that the heavy myelin fraction is enriched in paranodal
junctions. It also suggests that the contactin expressed by
oligodendrocytes (Einheber et al., 1997; Koch et al., 1997) is unlikely
to be present in compact myelin because it could not be detected in the
light myelin fraction.
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Figure 4.
Caspr and contactin cofractionate and coextract
from myelin fractions. Western blot analysis of Caspr and contactin in
myelin fractions and detergent extracts is shown. A,
Crude myelin preparations from rat brain homogenates are separated
further into light, medium, and heavy myelin fractions. The heavy
myelin fraction, which contains axonal and glial membranes, is enriched
in paranodal junctions, as indicated by the increased concentration of
Caspr (Cs). Contactin (Cn) is also
enriched in this fraction, whereas myelin basic protein
(MBP) is found in all of the fractions. Each lane was
loaded with 50 µg of total protein. B, Detergent
extracts were prepared from heavy myelin membranes, and the supernatant
(S) and insoluble pellet
(P) were evaluated for the presence of Caspr and
contactin. The distribution of myelin-associated glycoprotein
(MAG), a protein not found at the paranodal junctions,
was also examined. Caspr and contactin can be solubilized from a heavy
myelin preparation by sucrose monolaurate (SML) and
Zwittergent 3-14 (ZW 3-14) with or without 0.5 M NaCl. In the absence of salt Caspr and contactin, but
very little MAG, are extracted by ZW 3-14. In contrast, Triton X-100
solubilizes most of the MAG (STX),
whereas Caspr and contactin are mainly insoluble. These two proteins
could then be coextracted by ZW 3-14 from the Triton-insoluble pellet
(SZW).
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We next analyzed whether Caspr and contactin coextracted from the heavy
myelin preparation. Previously, we reported that Caspr was poorly
extracted from crude brain membrane preparations by a variety of
nonionic detergents, including Triton X-100 (Einheber et al., 1997). In
the current studies we used sucrose monolaurate (SML) and ZW 3-14. Both
detergents effectively solubilized Caspr and contactin from heavy
myelin fractions with or without salt (Fig. 4B).
Interestingly, when extractions were performed with ZW 3-14 in the
absence of salt, most of the Caspr and contactin were extracted whereas
MAG was not. Conversely, Triton X-100 extracted ~80% of the total
protein present in the heavy myelin fraction, including most of the
MAG, but Caspr and contactin were mainly insoluble, consistent with
previous studies (Einheber et al., 1997). These two proteins could then
be coextracted by ZW 3-14 from the Triton-insoluble pellet. Taken
together, the cofractionation and cosolubilization of Caspr and
contactin from heavy myelin fractions provide further support for an
interaction of these proteins in the paranodal junctions.
Caspr is associated with a PI-PLC-resistant form of contactin
To investigate whether Caspr is associated directly with contactin
before and after myelination, we performed a series of immunoprecipitations from SDS or nonionic detergent extracts of metabolically labeled neuron cultures or myelinating cocultures (Fig.
5). Labeled proteins were collected with
antibodies to Caspr or contactin or with the C-Fc construct,
fractionated by SDS PAGE, and analyzed with the PhosphorImager. As
expected, a protein with an Mr of
~190 kDa was immunoprecipitated consistently from SDS detergent
lysates of both neurons and cocultures with antibodies to Caspr (see
Fig. 5A, lanes a, g). Immunoprecipitation of
Caspr from nonionic detergent extracts of neurons and myelinating
cocultures also brought down approximately equivalent amounts of a 135 kDa protein, confirmed as contactin by parallel immunoprecipitation (Fig. 5A, lanes b, h). Similar
immunoprecipitation results were obtained when neurons and cocultures
were extracted with SML or ZW 3-14. In the case of ZW 3-14 the
interaction between Caspr and contactin was disrupted in the presence
of 500 mM NaCl, indicating that these two
proteins are associated via noncovalent, ionic interactions (data not
shown).
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Figure 5.
Caspr is complexed with a
lower-molecular-weight isoform of contactin. A,
Detergent extracts (1% SDS and 60 mM octyl glucoside) from
[35S]methionine-labeled neuron and myelinating
cocultures were subjected to immunoprecipitation with anti-Caspr serum
(lanes a, b, f, g, h), control preimmune
(PI) serum (lanes c, i),
anti-contactin serum (lane e), and the fusion protein
C-Fc (lane d). The autoradiogram shows a band
migrating at ~190 kDa (arrow) immunoprecipitated by
anti-Caspr antibodies, both from DRG (lanes a, b) and
myelinating cocultures (lanes g, h). Another protein
with an Mr ~135 kDa
(asterisk) was coimmunoprecipitated by the Caspr
antiserum from octyl glucoside extracts of DRG and myelinating
cocultures (lanes b, h), but not from SDS extracts
(lanes a, g). This band was identified as contactin by
parallel immunoprecipitation with C-Fc (lane
d) and contactin antiserum (lane e). Two
isoforms of contactin (arrowheads) were
immunoprecipitated from neurons, but only the lower-molecular-weight
PI-PLC-resistant isoform coimmunoprecipitates with Caspr
(lane f). B, Immunoprecipitates of
contactin from biotinylated DRG neurons were fractionated and analyzed
by Western blotting with streptavidin-peroxidase. Immunoprecipitates
were run on gels directly or were pretreated with PNGase F; the
two bands present in the untreated sample
(arrowheads) resolve as a major band
(arrowhead) after treatment. C, Western
blot of total homogenate and a myelin fraction prepared from sciatic
nerve probed with anti-contactin antibodies. D, ZW 3-14 detergent extracts from heavy myelin were incubated with C-Fc that
was coupled to Sepharose beads. Material bound to the beads was eluted
and analyzed by SDS-PAGE and Western blotting. The silver-stained gel
(left) and corresponding immunoblot
(right) demonstrate that Caspr (Cs) and
contactin (Cn) elute as part of a complex. Western blots
were developed sequentially with each antibody to demonstrate the
specificity of the staining; molecular weight markers are indicated on
the left.
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Of note, contactin antibodies and C-Fc each precipitated two
isoforms of contactin (Fig. 5A, lanes d, e),
consistent with our previous reports that DRGs express two contactin
isoforms (Rosen et al., 1992). Of particular interest, only the lower
contactin isoform coimmunoprecipitated with Caspr (indicated with an
asterisk in lanes b, h, Fig.
5A). In addition, treatment with PI-PLC did not affect the
association of Caspr with this lower-molecular-weight contactin isoform
(Fig. 5A, lane f). We had previously shown that the
upper, but not the lower, contactin isoform was released from DRG
neurons with PI-PLC treatment (Rosen et al., 1992). These results
suggest that the Caspr-associated isoform either is resistant to PI-PLC
activity or, if it is cleaved, remains at the cell surface because of
its interaction with Caspr.
Both of these isoforms are expressed at the cell surface because they
are labeled by external biotinylation (Fig. 5B). To investigate further the nature of the molecular weight difference between the two contactin isoforms, we treated immunoprecipitates of
contactin with PNGase F to remove N-linked carbohydrates. After deglycosylation these two contactin isoforms resolve as a major band
with an Mr of ~120 kDa, indicating
that they differ in the extent of their glycosylation (indicated with
an arrowhead, Fig. 5B); a minor band with a
slightly lower Mr may also be present.
To investigate the distribution of these isoforms in vivo,
we examined their expression in adult sciatic nerve, which contains both myelinated and nonmyelinated axons. Both isoforms are detectable in Western blots of sciatic nerve homogenates (Fig. 5C),
whereas only the lower isoform is detected in myelin fractions prepared from these nerves. Similarly, the lower isoform was coextracted selectively with Caspr by SML and ZW 3-14 (data not shown). These results demonstrate that the lower contactin isoform predominates in
myelinated nerves and, together with the immunofluorescence studies,
indicate that it is localized specifically in the paranodes with Caspr.
Of additional interest, the C-Fc appears to immunoprecipitate
preferentially the complex of Caspr and the smaller isoform of
contactin from neurons, whereas the contactin antibody recognized both
isoforms with a preference for the larger isoform (compare lanes
d, e, Fig. 5A). These latter results are
consistent with the distinct staining patterns of optic nerve by these
two reagents as noted above (see Fig. 2). As shown in Figure
5D, C-Fc also efficiently isolates a complex of Caspr
and contactin from detergent extracts of the heavy myelin fraction,
further supporting their association in this paranode-enriched
fraction. The relative excess of contactin visible on the gel is likely
to reflect the presence of oligodendrocyte membranes in this fraction
that contain contactin, but not Caspr.
Caspr and a subpopulation of contactin migrate at high
molecular weights
To characterize this junctional complex further, Caspr-enriched
detergent extracts were sized on sucrose density gradients. SML
extracts of DRG neurons and of myelinating cocultures were centrifuged
and the distribution of Caspr, contactin, and, in the case of
myelinating cocultures, MBP were analyzed (Fig.
6). In both extracts, Caspr migrated at
~550 kDa, which was recovered mainly in fractions corresponding to
23-36% sucrose. This is significantly >330 kDa, the expected
molecular weight for a Caspr-contactin dimer. A significant portion of
Caspr (30%), but not contactin, was also detected in the very
high-density fractions near the bottom of both gradients. The recovery
of Caspr in the heavier fractions of DRG neuron extracts suggests that
it is in larger complexes even before myelination. Its migration in
these heavier fractions independently of contactin may also indicate
that SML, which efficiently solubilizes both proteins (Peles et al.,
1997), partially disrupted their interactions.
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Figure 6.
Sucrose gradient analysis of Caspr and contactin
from detergent extracts. Sucrose monolaurate extracts of DRG neuron
(A) and myelinating cocultures
(B) were separated by centrifugation on a
10-45% sucrose gradient. The 1 ml fractions were collected from the
top of the gradient (fraction number 1) down to the
bottom (fraction number 12). Aliquots of 100 µl were
taken from each fraction and evaluated by Western blotting for the
presence of Caspr (Cs), contactin (Cn),
and myelin basic protein (MBP). Caspr migrates with an
average molecular weight of 550 kDa, with significant amounts at much
higher sizes, suggesting that it is part of a larger complex; the size
of this complex varies slightly from neurons to cocultures. Contactin
colocalizes with Caspr mainly in fractions 4-7 in
gradients prepared from neurons (A) and in
fractions 5-8 in gradients from myelinating cocultures
(B). A subpopulation of contactin, not associated
with Caspr, was recovered in the low-density fractions (fraction
3). As a control the bottom panel shows
the migration of MBP, a protein from compact myelin, which was
recovered mostly in fractions 2-4. The migration of
several molecular weight markers run in parallel, including gamma
globulin (150 kDa), apoferritin (440 kDa), and thyroglobulin (669 kDa),
is indicated at the bottom of the panel
(arrows).
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Contactin consistently migrated over a lower range of molecular
weights; it migrated with Caspr in some, but not all, of the fractions
recovered from the gradient. Based on the migration of the molecular
weight markers, the portion of contactin recovered in fractions F3-F4
may correspond to contactin monomers (molecular weight 135 kDa),
whereas contactin detected in the higher density fractions with Caspr
is presumably part of a high-molecular-weight complex. In support of
this possibility, contactin occasionally could be resolved into two
bands
with the upper band predominating in the lighter fractions and
the lower isoform in the heavier fractions that overlap with Caspr
(data not shown). Similar distribution patterns of Caspr and contactin
were observed on sucrose gradients of SML and ZW 3-14 extracts prepared
from CNS heavy myelin and homogenates of peripheral nerve, although in
these cases contactin appeared to migrate with Caspr more consistently
in the higher density fractions (data not shown).
RPTPC-Fc perturbs the localization of Caspr in
the paranodes
To examine further the cis interaction between Caspr
and contactin, we sequentially incubated DRG neurons with C-Fc and
a fluorescein-conjugated secondary antibody to human IgG. Cultures were
fixed immediately or incubated at 37°C to induce clustering and then
were double-stained for contactin, Caspr, or the L1 adhesion molecule,
as a control. In neurons that were fixed immediately, C-Fc,
contactin, Caspr, and L1 were all distributed diffusely on the neurites
(Fig. 7, 0 hr). In contrast, 6 hr of incubation with the secondary antibody induced striking
clustering of the bound C-Fc. Of note, contactin and Caspr
extensively colocalized with the clustered C-Fc, whereas L1
remained diffuse (Fig. 7, 6 hr). These results suggest that
most, if not all, of the Caspr is in a cis interaction with
contactin.
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Figure 7.
Cocapping of Caspr and contactin on DRG neurons.
Cultures of DRG neurons were incubated with C-Fc for 1 hr at 4°C,
followed by a 1 hr incubation at 4°C with anti-human secondary
antibodies (0 hr) and an additional 6 hr incubation at
37°C (6 hr) to induce clustering; in both instances
the cultures were fixed and processed for immunofluorescence. The
panels are composed of merged images with C-Fc
(fluorescein) and contactin, Caspr, and L1 stained with a rhodamine
secondary antibody. At 0 hr contactin (Cn), Caspr
(Cs), and L1 (L1) are each distributed
diffusely on the neurites. After a 6 hr incubation at 37°C, C-Fc
has induced clustering and cocaps with contactin and Caspr, but not
with L1. Scale bar, 10 µm.
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The strong affinity of C-Fc for the Caspr/contactin complex further
suggested that it might be useful in analyzing the targeting of this
complex to the paranodes. Because C-Fc contains the carbonic anhydrase domain of RPTP, a putative glial receptor for contactin, it potentially could block interactions of the Caspr/contactin complex
with glial cells and perturb its targeting. To investigate this
possibility, we placed neuron-Schwann cell cocultures in myelin-promoting media with or without C-Fc (25 or 100 µg/ml); the cultures were then maintained for several weeks in the respective media. In the presence of C-Fc, the cocultures myelinated normally, as indicated by comparable numbers of myelin segments (Fig.
8) and the level of MBP assessed by
Western blots of treated and control cultures (data not shown).
However, the distribution of Caspr in the treated cultures was
perturbed significantly in a dose-dependent manner (Fig. 8; quantified
in Table 1). At lower concentrations (25 µg/ml), abnormalities of Caspr staining were observed in ~60% of
the paranodes. The most common finding was the absence of staining at
the paranodes. Significant Caspr staining in the nodes of Ranvier and
proximal internodes was also much more common in treated than in
control cultures. At 100 µg/ml, Caspr clustering at the paranodes was
blocked completely. Interestingly, Caspr immunoreactivity appeared to
be reduced along myelinated internodes even in the treated cultures;
one example is located between the arrowheads in Figure 8, e
and f. These results indicate that binding of C-Fc to
the complex disrupts its targeting to the paranodes but may not block
its downregulation along the internode. These effects are C-specific
and do not result from the Fc domain, because normal staining was
observed in cultures treated with human IgG at 100 µg/ml (Fig.
8a). In initial studies no effect on the distribution of
Caspr was observed after treatment with L1-Fc, further underscoring
the specificity of this effect (data not shown).
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Figure 8.
C-Fc perturbs Caspr distribution in
myelinating cocultures. Cocultures were maintained in myelinating media
supplemented with human IgG (a, b) as a control or with
media supplemented with either 25 µg/ml (c, d) or 100 µg/ml (e, f) of C-Fc and stained for Caspr
and MBP. Control cultures (100 µg/ml IgG) displayed the normal
paranodal distribution of Caspr (Cs; rhodamine) and
normal myelin formation (MBP; fluorescein).
C-Fc-treated cultures (+C)
myelinate normally but exhibit concentration-dependent abnormalities of
Caspr localization, including the absence of Caspr at the paranodes
(white arrowheads), Caspr staining at the node
(asterisk), and Caspr staining throughout the internode
(white line). At the highest concentration, Caspr was
absent from essentially all paranodes. Scale bar, 50 µm.
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DISCUSSION |
In previous studies we presented evidence that Caspr and contactin
interact laterally in the membrane (Peles et al., 1997) but were able
to detect only Caspr in the paranodal junctions (Einheber et al.,
1997). Using new reagents, we now report that contactin and Caspr
indeed colocalize and form a complex in the paranodes and juxtamesaxon
and that treatment with C-Fc blocks their redistribution to the
paranodes. These results are considered further below.
Contactin and Caspr colocalize in the paranodes and juxtamesaxon,
but not in central nodes of Ranvier
A major finding of this study is that contactin is coexpressed
with Caspr in the paranodal and juxtamesaxonal domains. The paranodal
junctions have an emerging role in the domain organization of
myelinated axons (Peles and Salzer, 2000), whereas the physiological significance of the juxtamesaxon is unknown. It is observed principally in larger nerve fibers in the adult PNS and is rare in small myelinated nerve fibers in vivo and in vitro (data not
shown). The pattern of juxtamesaxonal staining suggests that it is
continuous with, and represents an internodal extension of, the inner
paranodal spiral (see Fig. 1; also see Arroyo et al., 1999).
Interestingly, delayed rectifier potassium channels, which are
concentrated in the juxtaparanodal region (Wang et al., 1993; Mi et
al., 1995), also flank Caspr in the juxtamesaxon and at sites apposing
Schmidt-Lanterman incisures (Arroyo et al., 1999). The Caspr/contactin
complex and flanking potassium channels may correspond to the rows of
symmetrical particle aggregates previously observed in freeze-fracture
studies of the juxtaparanodal and internodal axolemma (Stolinski et
al., 1985). Together, these results provide strong evidence that
noncompacted regions of the myelin sheath modulate the distribution of
axonal proteins in the paranodes, juxtaparanodes, and internodes.
Unexpectedly, contactin is also present in central, but not peripheral,
nodes of Ranvier where it is expressed independently of Caspr. The
contactin detected in central nodes is likely to be axonal because it
appears to be continuous with the staining observed in the adjacent
paranodes (see Fig. 2); however, a contribution from perinodal glial
processes cannot be excluded. These results thus provide the first
evidence of a difference in the molecular composition of peripheral
versus central nodes of Ranvier. The physiological role of contactin in
the central nodes is not yet known. Two contactin ligands, tenascin-R
and RPTP, also are expressed at the central nodes and have been
reported to interact with the sodium channel complex (Srinivasan et
al., 1998; Xiao et al., 1999; Ratcliffe et al., 2000). Interestingly,
tenascin-R is required for normal conduction velocity in the optic
nerve (Weber et al., 1999) and potentially could modulate conduction
velocity and nodal activity via interactions with contactin,
sodium channels, or both.
Caspr and contactin are components of a junctional complex
Consistent with their colocalization, Caspr and contactin form a
cis complex in the paranodal junctions. This complex does not assemble as a consequence of myelination but, rather, is preformed. Thus, these proteins cocap efficiently on neurons (see Fig. 7), coprecipitate from neurons and myelinating cultures equivalently (see
Fig. 5), and accumulate in the paranodal region with a similar time
course (see Fig. 3). It was reported recently that contactin is
required for the expression of Caspr/paranodin at the cell surface,
indicating that these proteins probably associate within the
endomembranous system (Faivre-Sarrailh et al., 2000). These two
proteins appear to interact with approximately equivalent stoichiometry
on the basis of immunoprecipitation. However, sucrose density gradient
analysis suggests that Caspr and contactin associate as a complex of
~550 kDa rather than the 330 kDa expected for a simple
contactin-Caspr dimer; these findings suggest that Caspr and contactin
may not form a simple heterodimer or that they may associate with other proteins.
Both cytoskeletal and signaling proteins are candidates to interact
with Caspr and contactin in the paranodes. The limited solubility of
Caspr in Triton X-100 (see Fig. 4) may reflect its association with
contactin, which directs it to detergent-insoluble microdomains
(Faivre-Sarrailh et al., 2000), or may indicate a cytoskeletal
association. Consistent with the latter possibility, ultrastructural
studies suggest the presence of a specialized cytoskeleton subjacent to
the paranodal junctions (Ichimura and Ellisman, 1991). In addition, the
cytoplasmic domain of Caspr is homologous to the region of glycophorin
that binds to band 4.1, a component of the erythrocyte cytoskeleton. A
potential interaction between the cytoplasmic domain of Caspr and band
4.1 was reported by Menegoz et al. (1997), although its physiological relevance is unclear at present. Several signaling molecules are also
candidates to interact with the proline-rich domain of the cytoplasmic
segment of Caspr, including PLC
, src, fyn, and the p85 subunit of
PI-3 kinase (Peles et al., 1997). In preliminary studies (J. Rios,
C. V. Melendez-Vasquez, and J. Salzer, unpublished observations)
we have been unable to confirm a paranodal localization for any of
these proteins or for PTP
, which was reported recently to associate
with contactin (Zeng et al., 1999).
Two forms of contactin differentially associate with Caspr
We and others previously reported the existence of two contactin
isoforms in the nervous system that are distinguishable by their
molecular weight and sensitivity to PI-PLC (Rosen et al., 1992; Olive
et al., 1995). Immunoprecipitation results in this study (see Fig. 5)
indicate that Caspr specifically associates with the
lower-molecular-weight PI-PLC-resistant form of contactin. In
agreement, the lower-molecular-weight isoform preferentially overlaps
with Caspr on sucrose gradients, coextracts with Caspr from sciatic
nerve, and specifically fractionates with PNS myelin. Together these
results indicate that this isoform is complexed with Caspr in the
paranodes and juxtamesaxon. The differences in molecular weight between
the two contactin isoforms reflect differences in the extent of
glycosylation (see Fig. 5B). Because contactin is likely to
associate with Caspr in the ER (Faivre-Sarrailh et al., 2000),
subsequent processing of its carbohydrates in the Golgi could be
affected. In potential agreement, F11, the chicken homolog of
contactin, is a mixture of two molecular species that contain either
complex or high mannose-type carbohydrates (Wolff et al., 1987). The
differential sensitivity of these contactin isoforms to PI-PLC is also
likely to reflect whether or not they are associated with Caspr; either
the lower contactin band is cleaved but remains attached to the cell
via its interaction with Caspr or, alternatively, it is insensitive to
PI-PLC. In the latter case, resistance to cleavage could reflect steric
hindrance because of its association with Caspr, although modifications
of its GPI anchor that render it PI-PLC-insensitive (Toutant et al.,
1990) are also a possibility.
The expression of two neuronal forms of contactin that differ in their
association with Caspr has important functional implications. Contactin
regulates neurite outgrowth, fasciculation, and axonal guidance
(Faivre-Sarrailh and Rougon, 1997), and Caspr has been proposed to
mediate the transmembrane signaling of the complex (Peles et al.,
1997). These contactin isoforms would have different functions in this
model because the nonassociated form might bind to a ligand without
signaling in contrast to the Caspr-associated form of contactin. The
association of Caspr also may regulate the interactions of contactin
with extracellular ligands (see below) and its targeting to specific
axonal domains. Of note, contactin that is complexed with Caspr is
localized to the paranodes of the optic nerve, whereas free contactin
is present in the adjacent nodes of Ranvier (see Fig. 2). Whether this
differential localization reflects unique interactions conferred on
contactin via its association with Caspr is of significant interest for
further investigation.
Targeting of the Caspr/contactin complex
We have shown that C-Fc binds to and completely blocks the
targeting of the Caspr/contactin complex to the paranodes (see Fig. 8).
Initial studies reveal significant abnormalities in this region,
including loss of normal septae, whereas compact myelin is unaffected
(J. Rios, S. Einheber, and J. Salzer, unpublished observations).
Further studies are in progress.
A likely mechanism by which the binding of C-Fc interferes with
targeting is by blocking interactions of this complex with presumptive
glial receptors. The glial receptor or receptors for Caspr and
contactin that promote their localization have not been identified;
indeed, it is not known whether these proteins have independent ligands
or are recognized as a complex. Contactin has a number of known
ligands, including itself (Gennarini et al., 1991), the adhesion
molecules Nr-CAM, Ng-CAM, and neurofascin (Brümmendorf et al.,
1993; Morales et al., 1993; Sakurai et al., 1997; Volkmer et al.,
1998), tenascin (Zisch et al., 1992; Pesheva et al., 1993), and RPTP
(Peles et al., 1995). We have detected expression of RPTP mRNA by
Schwann cells but have not observed a specific localization at the
paranodes in either the CNS or PNS (S. Scherer, J. Rios, J. Salzer,
unpublished observations). In contrast, the 155 kDa neurofascin isoform
is enriched in the paranodes (Davis et al., 1996) and recently was
identified as a glial component of the paranodal junctions (Tait et
al., 2000); it is therefore a candidate to bind directly or indirectly
to contactin in this site. Essentially nothing is known about the ligand or ligands for Caspr. The extracellular segment of Caspr contains a discoidin domain and neurexin repeats, each of which displays homology to lectin-binding domains (Rudenko et al., 1999). This homology and the significant abnormalities in the paranodal region
of mice deficient in galactocerebroside (Dupree et al., 1999) raise the
possibility that this myelin glycolipid is itself a ligand. An
alternate possibility is that other abnormalities in the myelin sheaths
of these mice indirectly affect paranodal interactions (Popko,
2000).
In summary, we have shown that Caspr and a subpopulation of contactin
form a complex on neurons that is targeted to the paranodal junctions,
potentially via extracellular interactions. Identification of other
junctional components, including the glial ligands for Caspr and
contactin, and analysis of contactin (Berglund et al., 1999) and Caspr
null mice also will further define the role of these proteins in
paranodal interactions.
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FOOTNOTES |
Received June 22, 2000; revised Aug. 21, 2000; accepted Aug. 24, 2000.
This work was supported by National Multiple Sclerosis Society Grant
RG-3102 and Grant 97-00093 from the United States-Israel Science
Foundation (BSF) to E.P., and by Grant NS38208 from the National
Institutes of Health (NIH) to J.L.S. J.C.R. is a Medical Scientist
Trainee supported by NIH Training Grant 5T32 GM07308 from National
Institute of General Medial Sciences. Elior Peles is Incumbent of the
Madeleine Haas Russell Career Development Chair. We thank Dr. T. Morimoto and Tian Huan Shen for advice with the sucrose gradient
analysis; J. Haspel for providing L1-Fc; Drs. T. Sakurai, S. Lambert,
and D. Colman for antibodies; Lee Cohen-Gould for assistance with
confocal microscopy; and Drs. G. Fishell, M. Phillips, and Deborah
Kittell for the use and assistance with their digital imaging facility.
J.C.R. and C.V.M.-V. contributed equally to the current study.
Correspondence should be addressed to Dr. James L. Salzer, Department
of Cell Biology, New York University Medical School, 550 First Avenue,
New York, NY 10016. E-mail: Jim.salzer{at}med.nyu.edu.
Dr. Grumet's present address: Department of Cell Biology and
Neuroscience, Keck Center for Collaborative Neuroscience, Rutgers, State University of New Jersey, Piscataway, NJ 08854.
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ABSTRACT
INTRODUCTION
