 |
 Previous Article | Next Article 
The Journal of Neuroscience, July 15, 1998, 18(14):5311-5321
The Neural Cell Adhesion Molecule L1 Interacts with the AP-2
Adaptor and Is Endocytosed via the Clathrin-Mediated Pathway
Hiroyuki
Kamiguchi1,
Kristin E.
Long1,
Maryanne
Pendergast1,
Andrew W.
Schaefer1,
Iris
Rapoport2,
Tomas
Kirchhausen2, and
Vance
Lemmon1
1 Department of Neurosciences, Case Western Reserve
University, Cleveland, Ohio 44106, and 2 Department of Cell
Biology and the Center for Blood Research, Harvard Medical School,
Boston, Massachusetts 02115
 |
ABSTRACT |
Cell-cell interactions mediated via cell adhesion molecules (CAMs)
are dynamically regulated during nervous system development. One
mechanism to control the amount of cell surface CAMs is to regulate
their recycling from the plasma membrane. The L1 subfamily of CAMs has
a highly conserved cytoplasmic domain that contains a tyrosine,
followed by the alternatively spliced RSLE (Arg-Ser-Leu-Glu) sequence.
The resulting sequence of YRSL conforms to a
tyrosine-based sorting signal that mediates clathrin-dependent
endocytosis of signal-bearing proteins. The present study shows that L1
associates in rat brain with AP-2, a clathrin adaptor that captures
plasma membrane proteins with tyrosine-based signals for endocytosis by
coated pits. In vitro assays demonstrate that this
interaction occurs via the YRSL sequence of L1 and the µ2 chain of
AP-2. In L1-transfected 3T3 cells, L1 endocytosis is blocked by
dominant-negative dynamin that specifically disrupts clathrin-mediated
internalization. Furthermore, endocytosed L1 colocalizes with the
transferrin receptor (TfR), a marker for clathrin-mediated
internalization. Mutant forms of L1 that lack the YRSL do not
colocalize with TfR, indicating that the YRSL mediates endocytosis of
L1. In neurons, L1 is endocytosed preferentially at the rear of axonal
growth cones, colocalizing with Eps15, another marker for the clathrin
endocytic pathway. These results establish a mechanism by which L1 can
be internalized from the cell surface and suggest that an active region
of L1 endocytosis at the rear of growth cones is important in
L1-dependent axon growth.
Key words:
neural cell adhesion molecule; L1; tyrosine-based sorting
signal; clathrin-mediated endocytosis; AP-2 adaptor; axonal growth
cone
| |
INTRODUCTION |
Cell adhesion molecules (CAMs) in
the immunoglobulin (Ig) superfamily play critical roles in neuronal
migration and axon growth and guidance (Brümmendorf and Rathjen,
1994 ). An important subfamily of Ig CAMs includes L1, neurofascin, and
NrCAM, which are expressed at relatively high levels on axons and
growth cones. The fact that humans and mice with L1 mutations have
defects in major axonal tracts confirms the importance of this class of
molecules (Cohen et al., 1997; Dahme et al., 1997; Fransen et al.,
1998; Kamiguchi et al., 1998).
For a cell to respond rapidly to changes in environmental situations,
the cell must be able to regulate the function and/or expression of its
CAMs. Little is known about how the function of L1 subfamily members is
regulated on a time scale of minutes, especially in neuronal growth
cones, where regulation via transcription or translation is not
possible locally. One way to control the amount of L1 on the cell
surface is to regulate its recycling from and to the plasma membrane.
Because it has been shown that integrins are endocytosed at the rear of
migrating cells and recycled to the front (Lawson and Maxfield, 1995;
Palecek et al., 1996), it is plausible that a similar phenomenon
occurs in growth cones advancing via an L1-dependent mechanism.
Clathrin-coated pits and vesicles provide for the rapid endocytosis of
plasma membrane proteins (Mellman, 1996). The cytoplasmic domains of
some membrane proteins contain tyrosine-based sorting signals that
direct clathrin-mediated endocytosis. Tyrosine-based signals conform to
the motif YxxØ, where x is any amino acid and Ø is an amino acid with
a bulky hydrophobic side chain (Trowbridge et al., 1993). The assembly
of clathrin coats at the plasma membrane depends on the adaptor complex
AP-2 (Gallusser and Kirchhausen, 1993), which is composed of two large
chains ( -adaptin and  1- or 2-adaptin), one medium chain
(µ2), and one small chain ( 2). The µ2 chain of AP-2 interacts
with the tyrosine-based signal (Ohno et al., 1995; Rapoport et al.,
1997) and concentrates the signal-bearing molecules in clathrin-coated
areas of the plasma membrane (Kirchhausen et al., 1997; Marks et al.,
1997).
L1 subfamily members have a highly conserved cytoplasmic domain
(Hortsch, 1996). Near the middle of the cytoplasmic domains is an
alternatively spliced RSLE (Arg-Ser-Leu-Glu) sequence (Miura et al.,
1991). In L1, the RSLE sequence is expressed in neurons, but not in
other L1-expressing cells such as Schwann cells (Takeda et al., 1996).
The RSLE sequence is preceded by a tyrosine in L1 subfamily members.
The resulting YRSL sequence conforms to the tyrosine-based sorting
signal YxxØ. We have found that the YRSL sequence mediates L1
endocytosis by interacting with AP-2. We also have found that
clathrin-dependent endocytosis of L1 preferentially occurs at the rear
of axonal growth cones. In this way the surface expression of L1 can be
regulated dynamically and spatially, which is likely to be crucial for
growth cone motility.
| |
MATERIALS AND METHODS |
Yeast two-hybrid system. The genotype of HF7c yeast
(Clontech Laboratories, Palo Alto, CA) is MATa ura3-52
his3-200 lys2-801 ade2-101 trp1-901 leu2-3,112 gal4-542
gal80-538 LYS2:: GAL1-HIS3 URA3:: (GAL4
17-mers)3-CYC1-lacZ. Yeast were grown on YEPD (yeast extract, peptone, dextrose) or on yeast minimal synthetic dextrose dropout media (C-nutrient), prepared as described previously (Nelson and Lemmon, 1993).
The cDNAs encoding the whole cytoplasmic domains of human
L1FL, L1Y1176A,
or L1 RSLE (see Fig. 1) were made
with PCR amplification of the L1FL,
L1Y1176A, or
L1RSLE cDNA in pBluescript II
KS+ (Wong et al., 1995; Kamiguchi and Lemmon, 1998),
respectively. The primers used were
5'-CGCCATGCCATGGTCAAGCGCAGCAAGGGC-3' and 5'-GCGGATCCACTATTCTAGGGCCAC-3'. The PCR products were subcloned into
PCR2.1 vecto, using a TA cloning kit (Invitrogen, Carlsbad, CA) and
then subcloned into the bait pAS vector (kind gift of Dr. Stephen J. Elledge, Baylor College of Medicine, Houston, TX). The entire
PCR-amplified region was confirmed by sequencing. The prey pACT vector
containing a cDNA encoding the µ2 chain of AP-2 (Ohno et al., 1996)
was provided by Dr. Juan S. Bonifacino (National Institutes of Health,
Bethesda, MD).
The HF7c strain was transformed sequentially with the pAS vector
containing the L1 cytoplasmic domain (L1CD) sequences and with the pACT
vector containing the µ2 chain sequence or no insert as a control.
Yeast transformation was performed as described in the Clontech Yeast
Two Hybrid Kit (Clontech Laboratories, Cambridge, UK).
Interactions between the three L1CD fusion proteins [baits in pAS2
(TRP1)] and the µ2 chain fusion protein [pACT
(LEU2)] were tested by the ability of cotransformed yeast
cells to express -galactosidase and to grow on histidine-deficient
plates. Cotransformed yeast colonies were grown on yeast dropout medium
lacking leucine and tryptophan (C-Leu-Trp), and then the cultures were
tested for -galactosidase activity by liquid assay as described
(Golemis et al., 1996). To test for HIS3 expression, we
streaked cells onto C-Leu-Trp-His plates in the presence of 5 or 10 mM 3-amino-triazole (3-AT). Growth was scored on the basis
of the ability to form colonies within 10 d (Ohno et al.,
1996).
Ultraviolet (UV)-induced cross-linking reaction. The
photoreactive peptide (designated as *YQRL), which bears a portion of the cytosolic sequence of TGN38, including its YQRL tyrosine-based motif, was synthesized as previously described (Rapoport et al., 1997).
The *YQRL peptide contains a UV-activatable cross-linker benzoylphenylalanine (BPA) at position Y-3 and is biotinylated at the N
terminus (biotin-KVTRRPK-BPA-SDYQRL). The YRSL peptide (FGEYRSLESD NEE) that corresponds to amino acids 1173-1185 of the
L1CD, the ARSL peptide (FGEARSLESDNEE) that has a Y1176A substitution, and the YSDN peptide (FGEYSDNEE) that lacks the RSLE sequence were
synthesized by Research Genetics (Huntsville, AL).
The photoactivation cross-linking reaction was performed as described
previously (Rapoport et al., 1997). Briefly, AP-2 complexes purified
from calf brains were suspended in AP buffer [containing (in
mM) 100 NaMES, 150 NaCl, 1 EDTA, and 0.5 DTT, pH 7.0, plus 0.02% NaN3 and 0.1% Triton X-100]. Then, 16 µl of this
solution (final AP-2 concentration of ~0.1 mg/ml) was mixed with 2 µl of the *YQRL peptide (final concentration of 0.2 µM)
and 2 µl of the competitor peptides (YRSL, ARSL, or YSDN peptide;
final concentrations in the range of 0-1000 µM). The
mixture was maintained on ice for 20 min in total darkness. The
cross-linking reaction was triggered by a 3 min exposure to UV
radiation. After the cross-linking reaction, 5 µl of 5× Laemmli
sample buffer containing -mercaptoethanol was added, and the samples
were boiled for 3 min. The cross-linked product was resolved by
SDS-PAGE, followed by transfer to a nitrocellulose membrane and
incubation with streptavidin-conjugated horseradish peroxidase (HRP;
Boehringer Mannheim, Indianapolis, IN). The labeled bands were detected
by enhanced chemiluminescence (Amersham, Arlington Heights, IL).
Immunoprecipitation and Western blot analysis. Brains from
P7 Sprague Dawley rat pups were homogenized in (in mM) 20 Tris, pH 7.4, 1 EGTA, 1 sodium orthovanadate, and 10 p-nitrophenyl phosphate (TEV-PNP) containing 0.32 M sucrose, 200 mM Pefabloc SC, 1µg/ml leupeptin, and 100 µg/ml aprotinin. The homogenates were separated by
ultracentrifugation on a sucrose gradient for 45 min at 58,400 × g at 4°C. The plasma membrane layer was washed in TEV-PNP
and then centrifuged for 30 min at 150,000 × g at
4°C to pellet the membranes. The plasma membrane pellet was
solubilized in TEV-PNP containing 1% Triton X-100 and centrifuged for
45 min at 150,000 × g at 4°C to remove insoluble
material. Then the solubilized membrane fraction was incubated for >4
hr at 4°C with Sepharose beads conjugated to monoclonal anti-L1
antibody 74-5H7 (Lemmon et al., 1989), or to monoclonal anti-NCAM
antibody 3F4 (kind gift of Dr. Urs Rutishauser, Case Western Reserve
University, Cleveland, OH). The beads were washed six times with
TEV-PNP containing 1% Triton X-100. Immunoprecipitates were mixed with
sample buffer and boiled for 5 min. Then the samples were separated by
SDS-PAGE. The proteins were transferred to Immobilon-P polyvinylidene
difluoride membrane (Millipore, Marlborough, MA), and the membrane then
was blocked with 5% evaporated nonfat milk in Tris-buffered saline (TBS). The following commercial primary antibodies were used as recommended by the manufacturer: monoclonal antibodies against AP180,
1- and 2-adaptin, and -adaptin (Sigma, St. Louis, MO). The
monoclonal anti-NCAM antibody (3F4) was used at 10 µg/ml. The
membrane was incubated with primary antibodies for 1 hr at room
temperature with shaking and was washed with 0.1% Tween-20 in TBS.
Then the membrane was probed with HRP-conjugated goat anti-mouse IgG
(1:1000 in 5% milk and 0.05% Tween-20/PBS, Boehringer Mannheim) for 1 hr, washed, and visualized by enhanced chemiluminescence (DuPont NEN,
Boston, MA).
Cell culture. National Institutes of Health-3T3 (NIH-3T3)
cells (American Type Culture Collection, Rockville, MD) were grown in
DMEM (Life Technologies, Gaithersburg, MD) supplemented with 10% fetal
bovine serum (FBS).
Dorsal root ganglia (DRGs) were dissected from embryonic day 10 chicks
and dissociated sequentially with 2.4 U/ml dispase II (Boehringer
Mannheim) and 0.1 mg/ml DNase (Boehringer Mannheim) in
Ca2+/Mg2+-free PBS. The
dissociated cells were resuspended in RPMI medium 1640 (Life
Technologies) supplemented with L-glutamine, Na pyruvate, and 10% FBS and were preplated for 1 hr. Then 50 ng/ml nerve growth factor was added to the medium, and the neuron-enriched culture was
prepared by replating the detached cells on glass coverslips sequentially coated with poly-L-lysine (Sigma), 10 µg/ml
goat anti-human IgG (Fc-specific) (Sigma), and L1-Fc chimera. This chimeric molecule, which consists of the Fc region of human IgG and the
whole extracellular domain of human L1, was constructed with the
pIg-tail expression system (Novagen, Madison, WI), as described
(Fransen et al., 1998).
The cultures were maintained in a humid atmosphere of 95% air/5%
CO2 at 37°C.
DNA transfection. A pcDNA3-based expression plasmid
containing a cDNA insert that codes for L1FL,
L1Y1176A, or
L1RSLE (see Fig. 1) was constructed
as described (Kamiguchi and Lemmon, 1998). Expression constructs
containing a cDNA insert that codes either for hemagglutinin
(HA)-tagged wild-type or for HA-tagged K44A dynamin were provided by
Dr. Sandra L. Schmid (The Scripps Research Institute, La Jolla, CA)
(Damke et al., 1994).
NIH-3T3 cells were transfected with the L1 expression plasmids, using
particle-mediated gene transfer (Helios Gene Gun System, Bio-Rad,
Richmond, CA). According to the manufacturer's protocol, 50 mg of gold
particles (1.0 µm in diameter) was coated with 100 µg of plasmid
DNA. Then the DNA-coated particles in an ethanol suspension were loaded
into Gold-Coat tubing and allowed to dry. NIH-3T3 cells were
dissociated by trypsinization and resuspended in Leibovitz's L-15
medium (Life Technologies). Ten microliters of the cell suspension
(1 × 106 cells) were inoculated in the center
of a 35 mm dish immediately before the gene delivery. For each
transfection, 0.5 mg of gold particles with 1 µg of plasmid DNA was
accelerated by 150 psi helium pressure to penetrate and transfect the
target cells. The transfected cells were suspended in DMEM containing
10% FBS and plated on a two-chamber plastic slide (Lab-Tek,
Naperville, IL) sequentially coated with poly-L-lysine and
5 µg/cm2 of fibronectin (Boehringer Mannheim).
Transfection of NIH-3T3 cells with the HA-tagged dynamin constructs was
performed by
N-[1-(2,3-dioleoyloxy)propyl]-N,N,N-trimethylammonium methylsulfate (DOTAP) lipofection, according to the manufacturer's protocol (Boehringer Mannheim).
Generation of stably transfected NIH-3T3 cells. NIH-3T3
cells were transfected with pcDNA3 containing L1FL cDNA,
using Lipofectamine reagent according to the manufacturer's protocol
(Life Technologies). The cells were cultured in the presence of 600 µg/ml of G418 (Life Technologies) for 10-14 d. G418-resistant clones
were characterized for L1FL expression by
immunocytochemistry, and L1FL-expressing cells were
selected by fluorescence-activated cell sorting (FACS) as described
previously (Wong et al., 1995). The cells were grown further in 10%
FBS-DMEM containing 600 µg/ml of G418.
Immunocytochemistry of NIH-3T3 cells. L1-transfected NIH-3T3
cells were processed for immunocytochemistry 24 hr after gene transfer.
In the experiment designed to label cell surface and endocytosed L1
differentially, living cells were incubated with rabbit polyclonal
anti-human L1 antibody (1:250) (Wong et al., 1995) or Fab of the same
antibody (25 µg/ml) for 1 hr at 37°C to allow for L1 endocytosis.
Then the cells were washed with DMEM at 4°C and were incubated with
Texas Red (TxR)-conjugated anti-rabbit IgG (1:200; Molecular Probes,
Eugene, OR) for 30 min at 4°C to visualize cell surface L1. Then
unlabeled anti-rabbit IgG (1:20; Molecular Probes) was used to block
any remaining sites on the cell surface for 1 hr at 4°C. The cells
were fixed with 4% paraformaldehyde for 30 min, followed by blocking
and permeabilization with 10% horse serum (HS) and 0.02% Triton X-100
in PBS. After washes, the cells were incubated with Oregon green
(OrG)-conjugated anti-rabbit IgG (1:200; Molecular Probes) for 1 hr at
20°C to label endocytosed L1-antibody complexes.
In the experiment designed to double-label endocytosed L1 and
transferrin receptors (TfR), endocytosed L1 was visualized as described
above, and TfR was labeled with mouse monoclonal anti-TfR antibody
(clone H68.4; Zymed Laboratories, San Francisco, CA). Living cells were
incubated with Fab of rabbit anti-L1 antibody (25 µg/ml) for 1 hr at
37°C, washed at 4°C, and incubated with unlabeled anti-rabbit IgG
(1:20) for 1 hr at 4°C. After fixation, blocking, and
permeabilization, the cells were incubated with anti-TfR antibody
(1:100) for 16 hr at 4°C. Then the cells were incubated with
OrG-conjugated anti-rabbit IgG (1:200) to visualize endocytosed L1 and
with TxR-conjugated anti-mouse IgG (1:200) to visualize TfR.
In the experiment designed to visualize endocytosed L1 and
transferrin (Tf), living cells were incubated with serum-free DMEM for
30 min, followed by incubation with rabbit anti-L1 antibody (1:250) and
TxR-conjugated Tf (100 µg/ml; Molecular Probes) for 1 hr at 37°C to
allow for the endocytosis of both probes. The cells were incubated with
unlabeled anti-rabbit IgG, followed by fixation, blocking, and
permeabilization. Endocytosed L1 was visualized with OrG-conjugated
anti-rabbit IgG.
In the experiment to study the effects of wild-type and K44A dynamin on
L1 endocytosis, L1FL-expressing NIH-3T3 cells (stable transfectant, selected by FACS) were transfected with HA-tagged dynamin
constructs and processed for immunocytochemistry after 48 hr.
Endocytosed L1 was labeled with rabbit anti-L1 antibody as described
above, and then the cells were incubated with unlabeled anti-rabbit
IgG, followed by fixation, blocking, and permeabilization. HA-tagged
dynamin was labeled by incubating the cells with mouse monoclonal
anti-HA antibody (clone 12CA5, 10 µg/ml; Boehringer Mannheim) for 16 hr at 4°C. After being washed, the cells were incubated with a
mixture of TxR-X-conjugated anti-rabbit IgG (1:100; Molecular Probes)
and OrG-conjugated anti-mouse IgG (1:200; Molecular Probes). The
labeled cells were mounted with SlowFade (Molecular Probes).
Immunocytochemistry of DRG neurons. In the experiment
designed to double-label L1 (74-5H7) and epidermal growth factor
receptor pathway substrate clone 15 (Eps15), DRG cultures were fixed
sequentially with (1) a cyclohexylamine/PIPES fixative containing 1%
paraformaldehyde for 5 min (Luther and Bloch, 1989), followed by (2) a
modified Bouin's solution containing saturated picric acid (75 ml),
formalin (5 ml), glacial acetic acid (5 ml), and distilled water (20 ml) for 5 min. After extensive washes, the cells were permeabilized and
blocked with 10% HS and 0.02% Triton-X 100 in PBS for 1 hr and
incubated with primary antibodies overnight at 4°C. The primary antibodies used were mouse monoclonal anti-L1CD antibody (74-5H7; 1:500) (Lemmon et al., 1989) and rabbit polyclonal anti-Eps15 antibody
(1:500) (Cupers et al., 1997). After being rinsed, the cells were
incubated for 1 hr at room temperature with a mixture of OrG-conjugated
anti-rabbit IgG (1:200) and TxR-X-conjugated anti-mouse IgG (1:100;
Molecular Probes).
In the experiment designed to visualize endocytosed L1 in growth cones,
living DRG neurons were incubated with rabbit polyclonal anti-chick L1
antibody (8D9; 1:250) (Lemmon and McLoon, 1986) for 15 min at 37°C to
allow for L1 endocytosis. After being rinsed at 4°C, the cells were
fixed with 4% formaldehyde for 30 min, washed, and incubated with
unlabeled anti-rabbit IgG (1:20) to block the cell surface primary
antibody. Then the cells were fixed again with 4% formaldehyde for 10 min to immobilize the unlabeled secondary antibody. After being washed,
the cells were permeabilized and blocked with 10% HS and 0.02%
Triton-X 100 in PBS for 1 hr and incubated with mouse monoclonal
anti-chick NCAM antibody (kind gift of Dr. Urs Rutishauser) for 16 hr
at 4°C. Endocytosed L1 was visualized with TxR-X-conjugated
anti-rabbit IgG (1:100), and NCAM was visualized with OrG-conjugated
anti-mouse IgG (1:200). The labeled cells were treated with SlowFade
and mounted in Elvanol.
Confocal microscopy. Images of NIH-3T3 cells and growth
cones of DRG neurons were taken with a Zeiss LSM 410 confocal laser microscope (Zeiss, Göttingen, Germany), using an argon/krypton laser (excitation lines, 488 and 568 nm) and a 100× Plan-Neofluar, numerical aperture 1.3, oil objective.
L1 and Eps15 distribution in growth cone images was analyzed by the
colocalization function in the LSM 410 software (Zeiss). The program
generates a scatterplot that compares pixel distribution and intensity
in stored red and green images. Red pixels of increasing intensity
(0-255) distribute along the abscissa; green pixels distribute along
the ordinate. Pixels with identical intensity values in the green and
red channels are found along the 45° diagonal and indicate
colocalization of the fluorescently tagged antibodies that are used to
detect different antigens. By selecting pixels near the 45° diagonal,
we can generate a mask that allows for the direct comparison of the
colocalization of two antigens with the unprocessed image. Only high
intensity pixels falling near the diagonal were selected to generate
the mask showing colocalized distribution of L1 and Eps15. Images were
processed minimally; montages were assembled in Adobe Photoshop and
printed on a Tektronix Phaser 450 dye sublimation printer.
| |
RESULTS |
The µ2 chain of AP-2 specifically recognizes and interacts with
the tyrosine-based motif YRSL in the L1CD
To test whether the tyrosine-based sorting motif YRSL in the L1CD
interacts with the µ2 chain of AP-2, we used the yeast two-hybrid assay, using the whole L1CD as the bait fused to the Gal4 binding domain and the µ2 chain as the prey fused to the Gal4 activation domain. The cytoplasmic domains of wild-type and mutant forms of L1
(L1FLCD, L1RSLECD, and
L1Y1176CD) used in the yeast two-hybrid assay are shown in Figure 1. Interactions
between the three forms of L1CD and the µ2 chain were tested by the
ability of cotransformed yeast cells to grow on histidine-deficient
plates or to express -galactosidase activity. On C-Leu-Trp plates,
which select for the presence of the bait and prey vectors, all double
transformants were able to grow and produce colonies between 1 and
3 d after plating. However, on histidine-deficient plates
(C-Leu-Trp-His) in the presence of 3-AT (5 or 10 mM), only
double transformants expressing L1FLCD and µ2 grew and
produced colonies between 3 and 5 d (Fig.
2A). All of the other
transformants did not form colonies after 10 d under the same
conditions. Similar results were obtained with 5 and 10 mM
3-AT. The -galactosidase liquid assay showed that yeast cells
cotransformed with pAS containing the L1FLCD sequence and
pACT containing the µ2 chain sequence expressed a significantly
higher level of -galactosidase activity than the control strain,
which carried pAS with the L1FLCD sequence and empty pACT
(Fig. 2B). However, the -galactosidase activity of
yeast cells that were cotransformed with pAS containing either the
L1Y1176ACD or
L1RSLECD sequence and pACT containing
the µ2 chain sequence was comparable to the control level. These
results demonstrate that the L1FLCD, but not
L1Y1176ACD or
L1RSLECD, interacts with the isolated
µ2 chain of AP-2.
View larger version (19K):
[in this window]
[in a new window]
|
Figure 1.
A portion of the L1 cytoplasmic domain is shown in
the single-letter amino acid code. In the wild-type full-length L1
(L1FL), the cytoplasmic domain consists of
114 amino acids (1144-1257) and contains the RSLE sequence
(shaded region), which is adjacent to
Tyr1176. The resulting sequence of YRSL conforms to
a tyrosine-based sorting motif, YxxL (underlined
region). L1Y1176A
has a single amino acid substitution (Y1176A) that
mutates a critical tyrosine residue in the motif. In the non-neuronal
form of L1 (L1RSLE)
that lacks the RSLE sequence, a hydrophobic amino acid leucine at
position Y+3 is replaced by a polar amino acid asparagine. Therefore,
the tyrosine-based motif YRSL is disrupted in
L1Y1176A and
L1RSLE. A cDNA that codes for the
whole cytoplasmic domain of these forms of L1 (L1FLCD,
L1RSLECD, or
L1Y1176ACD) was used in the
yeast two-hybrid system. The synthetic peptides (YRSL,
ARSL, and YSDN), which correspond
to a part of L1FLCD,
L1RSLECD, or
L1Y1176ACD, respectively,
were used as a competitor in the UV-induced cross-linking
experiments.
|
|
View larger version (47K):
[in this window]
[in a new window]
|
Figure 2.
The yeast two-hybrid assay demonstrates the
interaction between the YRSL sequence of the L1CD and the µ2 chain of
AP-2. A, Yeast cells, which were cotransformed with
L1FLCD and µ2 sequences
(L1FL-µ2), were able to grow and form
colonies on histidine-deficient plates in the presence of 5 mM 3-AT between 3 and 5 d after plating. However,
cotransformants containing either
L1RSLECD or
L1Y1176ACD and µ2
sequences (L1RSLE-µ2 or
L1Y1176A-µ2, respectively) did not form
colonies after 10 d under the same conditions.
B, L1FL-µ2 expressed a
significantly higher level of -galactosidase activity than a
background level (L1FL-Empty). However, both
L1RSLE-µ2 and
L1Y1176A-µ2
expressed comparable levels of -galactosidase activity to the
background level. Values represent the mean ± SD of five
determinations. *p < 0.0005; one-way ANOVA,
followed by post hoc Fisher's PLSD as compared with
L1FL-Empty.
|
|
In previous studies it has been demonstrated that a photoreactive
peptide (*YQRL) bearing a portion of the cytosolic sequence of TGN38,
including its tyrosine-based sorting motif, specifically labels the
µ2 subunit of the intact AP-2 complex (Rapoport et al., 1997). To
test whether the synthetic peptide, including the YRSL sequence in the
L1CD, also interacts with the µ2 chain, we set up an experiment in
which a biotinylated *YQRL peptide was incubated with purified AP-2 in
the presence of increasing concentrations of the L1CD peptides (YRSL,
ARSL, and YSDN peptides; see Fig. 1). After photoactivation, samples
were analyzed by SDS-PAGE and probed with HRP-streptavidin to reveal
the product composed of µ2 cross-linked to *YQRL (Fig.
3). The YRSL peptide interfered with the
cross-linking reaction between the *YQRL peptide and the µ2 chain.
This competitive interaction of the YRSL peptide is dependent on its
tyrosine residue, because the ARSL peptide did not interfere with the
cross-linking reaction. Further confirmation of the specificity of the
interaction was obtained by showing that another peptide, YSDN, also
failed to interfere with the cross-linking reaction. On the basis of
these observations, we conclude that the interaction between the YRSL
peptide and the AP-2 complex in solution is specific and that this
interaction occurs through a contact that involves the µ2 chain of
the AP-2 complex.
View larger version (29K):
[in this window]
[in a new window]
|
Figure 3.
The µ2 chain of AP-2 was labeled by the *YQRL
peptide containing photoreactive cross-linker in the absence or
presence of the competitor peptides (YRSL,
ARSL, or YSDN; see Fig. 1). The
concentrations of each competitor peptide are indicated in the figure.
The YRSL peptide that carries the tyrosine-based motif interfered with
the cross-linking reaction between the *YQRL peptide and the µ2 chain
when the YRSL peptide was presented at a concentration as low as 10 µM. Both the ARSL and YSDN
peptides lacking the motif failed to interfere with the cross-linking
reaction at concentrations up to 1 mM.
|
|
The AP-2 complex associates with L1 in rat brain
In vitro biochemical assays have shown that the YRSL
sequence in the L1CD specifically binds the µ2 chain of AP-2. To
examine whether L1 associates with AP-2 in vivo, we probed
L1 immunoprecipitates from rat brain membrane extracts with antibodies
against two of the subunits of AP-2 and against AP180. Anti-1- and
2-adaptin antibody labeled a band of ~105 kDa (Fig.
4, lane 2).
Anti--adaptin antibody, which is known to react with 105 and 110 kDa
forms of -adaptin in brain preparations (Ahle and Ungewickell,
1990), labeled two bands of the corresponding sizes in L1
immunoprecipitates (Fig. 4, lane 3). These data indicate
that the AP-2 complex associates with L1 in rat brain. AP180, which is
a clathrin assembly protein in coated vesicles (Ahle and Ungewickell,
1986), coimmunoprecipitated with L1 (Fig. 4, lane 1),
further confirming that L1 forms a complex with clathrin-associated
proteins in brain. As a negative control, antibodies to NCAM readily
detected NCAM in the brain membrane extracts (Fig. 4, lane
5), but not in the L1 immunoprecipitate (Fig. 4, lane
4). Another negative control is provided in Figure 4
(lanes 7-10), which shows that neither AP-2 nor AP-180
coimmunoprecipitated with NCAM from rat brain membrane extracts.
View larger version (55K):
[in this window]
[in a new window]
|
Figure 4.
L1 immunoprecipitates from rat brain membrane
extracts were probed with anti-AP180 antibody (lane 1),
anti-1- and 2-adaptin antibody (lane 2) or
anti--adaptin antibody (lane 3), and no primary
antibody control (lane 6), showing that AP-2 and
AP180 coimmunoprecipitated with L1. As a control, the L1
immunoprecipitates (lane 4) and rat brain
membrane extracts (lane 5) were probed with anti-rat
NCAM antibody. As another control, NCAM immunoprecipitates from rat
brain membrane extracts were probed with anti-AP180 antibody
(lane 7), anti-1- and 2-adaptin antibody
(lane 8), anti--adaptin antibody (lane
9), or anti-NCAM antibody (lane 10).
|
|
L1 is endocytosed via a clathrin-mediated pathway
The interaction of the AP-2 adaptor with the tyrosine-based signal
of the L1CD suggests that L1 is endocytosed via an AP-2 and
clathrin-mediated pathway. Therefore, we examined whether or not L1 is
internalized from the cell surface, using L1FL-transfected NIH-3T3 cells. Since it is difficult to visualize L1 clearly in intracellular vesicular compartments by conventional
immunocytochemistry because of a much higher level of L1 expression on
the cell surface, we used two secondary antibodies with different
conjugates to label cell surface L1 and endocytosed L1 differentially.
Intracellular L1 in vesicular compartments, possibly endosomes, are
shown clearly in L1FL-transfected NIH-3T3 cells (Fig.
5A,B).
Labeling of these structures is specific for L1, because the cytoplasm
of untransfected NIH-3T3 cells was never labeled under this
immunocytochemical protocol (data not shown). Furthermore, because the
cells were incubated with anti-L1 antibody only when they were alive,
all of the positive staining inside the cell represents endocytosed L1.
This observation demonstrates that L1 is internalized from the cell
surface. A bivalent antibody against L1 tended to label a greater
number of intracellular structures than Fab, suggesting that
cross-linking L1 on the cell surface triggers endocytosis of L1. As
shown in Figure 5B, we often observed L1 in endocytic compartments enriched in one side of the cell near the lateral membrane.
View larger version (78K):
[in this window]
[in a new window]
|
Figure 5.
A, B, Shown are
confocal sections (0.83 µm in thickness) of
L1FL-transfected NIH-3T3 cells in which cell surface L1 and
endocytosed L1 were differentially labeled. Living cells were incubated
with bivalent anti-L1 antibody (A) or anti-L1 Fab
(B) for 1 hr to allow for L1 endocytosis. A
superimposed image in which cell surface L1 is colored in
red and endocytosed L1 in green is shown.
Scale bar, 10 µm. C-E, Confocal
sections (0.83 µm in thickness) of a L1FL-transfected
NIH-3T3 cell that was incubated with anti-L1 antibody and
TxR-conjugated Tf for 1 hr to allow for the endocytosis of both probes.
Shown are endocytosed L1 (C), endocytosed Tf
(D), and a superimposed image showing
colocalization of L1 and Tf as evidenced by yellow
(E). Scale bar, 10 µm.
F-I, Confocal sections (0.71 µm in
thickness) of L1FL-expressing NIH-3T3 cells that were
transfected with K44A dynamin (F, G) or
wild-type dynamin (H, I).
Endocytosed L1 is colored in red and transfected dynamin
in green (F, H). To
facilitate the visualization of endocytosed L1, we have shown the red
channel only in black and white
(G, I). An asterisk
indicates a cell that was not transfected with K44A dynamin. Scale bar,
10 µm.
|
|
Subsequently, we conducted experiments to study whether or not L1
endocytosis occurs via a clathrin-dependent pathway. Transferrin (Tf)
is known to be internalized via a clathrin-mediated mechanism after
binding to a transferrin receptor TfR (Klausner et al., 1983;
Trowbridge et al., 1993), which carries a tyrosine-based endocytic
signal that interacts with AP-2 (Ohno et al., 1995). We found that, in
L1FL-transfected NIH-3T3 cells, all of the endocytosed L1FL labeled by anti-L1 antibody was found in vesicular
compartments (most likely endosomes) that contained TxR-Tf (Fig.
5C-E), indicating that L1 endocytosis occurs via
the same pathway as that of Tf. To confirm further that L1 endocytosis
is clathrin-dependent, we tested whether disruption of dynamin function
blocks L1 endocytosis. Dynamin, a member of the GTPase superfamily,
self-assembles into rings at the neck of clathrin-coated pits and plays
a critical role in the fission reaction to form coated vesicles
(Hinshaw and Schmid, 1995; Takei et al., 1995). Dominant-negative
dynamin, which has a K44A mutation in its GTP-binding domain,
specifically blocks the formation of endocytic coated vesicles but does
not perturb clathrin-independent endocytosis (van der Bliek et al., 1993; Damke et al., 1994). Therefore, we set up an experiment in which
L1FL-expressing NIH-3T3 cells were selected by FACS and transfected with HA-tagged wild-type or K44A dynamin. Then the cells
were processed for immunocytochemistry to visualize endocytosed L1. A
single-section confocal slice of a dynamin-transfected cell was
obtained such that the section contained the maximal number of
intracellular L1-positive compartments in that cell. K44A
dynamin-transfected cells showed impaired L1 endocytosis as compared
with untransfected (Fig. 5F,G) and
wild-type dynamin-transfected cells (Fig.
5H,I). L1 endocytosis was
semiquantified by counting the number of intracellular L1-positive
compartments per cell: 3.7 ± 3.6 in K44A dynamin-expressing cells
(n = 33) and 26.3 ± 20.6 in wild-type
dynamin-expressing cells (n = 32) (mean ± SD;
p < 0.0001; unpaired Student's t test). We
also confirmed that K44A dynamin blocks Tf endocytosis but does not
affect dextran uptake, a marker for clathrin-independent pinocytosis
(data not shown). These results provide solid evidence that L1 is
endocytosed via clathrin-coated vesicles.
To examine the role for the YRSL sequence in L1 endocytosis, we
transfected NIH-3T3 cells with an L1FL,
L1Y1176A, or
L1RSLE construct. These forms of L1
have been shown to be integrated properly into the plasma membrane in
NIH-3T3 cells (Kamiguchi and Lemmon, 1998). All of the endocytosed
L1FL, which was labeled by anti-L1 Fab, was found in
vesicular compartments containing TfR (Fig.
6A-C).
Although both L1Y1176A and
L1RSLE were internalized from the cell
surface, these forms of L1 did not colocalize with TfR in their
endocytic pathways (Fig. 6D-I). The failure
of the L1 mutants to colocalize with the TfR supports the idea that the YRSL sequence is critical for determining the pathways by which L1 is
endocytosed.
View larger version (191K):
[in this window]
[in a new window]
|
Figure 6.
Confocal sections (0.83 µm in thickness) of
NIH-3T3 cells expressing L1FL
(A-C),
L1Y1176A
(D-F), or
L1RSLE
(G-I). Living cells were
incubated with anti-L1 Fab for 1 hr to label endocytosed L1, and the
cells were double-labeled with anti-TfR antibody. Endocytosed L1
(A, D, G), TfR
(B, E, H), and
superimposed images (C, F,
I) are shown. Yellow indicates
colocalization of endocytosed L1 and TfR. Scale bar, 10 µm.
|
|
L1 is endocytosed at the rear of axonal growth cones
Homophilic binding between substrate-bound L1 and axonal L1
stimulates axon growth in vitro (Lemmon et al., 1989). In
the axonal growth cone, L1-mediated adhesive interactions may be
dynamically regulated to create a front-versus-rear asymmetry in growth
cone-substrate adhesion (Kamiguchi and Lemmon, 1997). This is believed
to be necessary for growth cone migration (Lauffenburger and Horwitz, 1996). One possible mechanism to create a gradient of adhesivity is
that L1 is internalized from the growth cone surface in a spatially regulated manner. To confirm this possibility, we examined
colocalization of L1 and Eps15, a protein present in coated pits of the
clathrin-mediated endocytic pathway (Tebar et al., 1996; van Delft et
al., 1997), in DRG growth cones growing on an L1 substrate. We used a
monoclonal antibody, 74-5H7 (Lemmon et al., 1989), that binds to a
phosphorylation-sensitive site in the L1CD and does not label cell
surface L1 except at cell-cell contact sites (A. W. Schaefer, S. Storms, G. Landreth, and V. Lemmon, unpublished observations). This
antibody labeled vesicular structures in the growth cone (Fig.
7A). The growth cone was
double-labeled with anti-Eps15 antibody (Fig. 7B), showing the concentrated expression of Eps15 at the rear of the growth cone
where L1 and Eps15 had colocalized (Fig. 7C). This
colocalization pattern was confirmed further by using the
colocalization function in the LSM 410 software (Fig. 7D).
The site-specific colocalization of L1 and Eps15 suggests that
clathrin-mediated endocytosis of L1 preferentially occurs at the rear
of growth cones. To confirm this idea further, we visualized
intracellular L1 that had been endocytosed during 15 min in DRG growth
cones growing on an L1 substrate (Fig.
7E,F). In the majority of
growth cones examined, endocytosed L1 is restricted to the rear and the
central domain of the growth cone and is absent from the peripheral
domain.
View larger version (87K):
[in this window]
[in a new window]
|
Figure 7.
A-D, Confocal
sections (0.71 µm in thickness) of a DRG growth cone growing on an L1
substrate. The growth cone was double-labeled with anti-L1CD antibody
(74-5H7) (A) and anti-Eps15 antibody
(B). Superimposition of the images with L1
colored in red and Eps15 in green
exhibits colocalization (yellow) at the rear of
the growth cone (C). A black and
white mask shows the colocalized distribution of L1 and
Eps15 (D). High intensity pixels falling within
the green tracing on the scatterplot
(inset) were chosen to generate the mask (see Materials
and Methods for details). Scale bar, 10 µm. E,
F, Confocal sections (0.83 µm in thickness) of a DRG
growth cone growing on an L1 substrate. The living neuron was incubated
with anti-L1 antibody for 15 min to label endocytosed L1. The cell was
double-labeled with anti-NCAM antibody to visualize the outline of the
growth cone. Endocytosed L1 is colored in red and NCAM
in green (E). To facilitate
visualization of endocytosed L1, we have shown the red channel only in
black and white
(F). Scale bar, 10 µm.
|
|
| |
DISCUSSION |
Examples of cells rapidly altering CAM function are found in
diverse systems, from leukocyte rolling and extravasation through the
vascular endothelium to synaptic plasticity in the nervous system
(Ebnet et al., 1996; Fields and Itoh, 1996; Rutishauser and Landmesser,
1996; Weber et al., 1996). A common strategy for controlling CAM
function is to regulate the adhesivity of the extracellular domain by
changing the conformation of its cytoplasmic tail. This inside-out
signaling has been well documented for integrins and cadherins (Aberle
et al., 1996; Kolanus and Seed, 1997). However, it is known that
removing the cytoplasmic domain of L1 and its Drosophila
homolog, neuroglian, does not alter their adhesivity (Hortsch et al.,
1995; Wong et al., 1995). This suggests that alterations, such as
phosphorylation or conformational changes, in the L1CD may not regulate
the adhesivity of its extracellular domain directly. Therefore, another
strategy may be used to alter L1-mediated adhesion. For example, the
amount of L1 expression on the cell surface could be controlled by
regulating its internalization from the plasma membrane.
The interaction between cytoplasmic coat proteins and specific signals
in the cytoplasmic tails of integral membrane proteins is considered a
general mechanism for controlling protein sorting in the endocytic
pathways. The tyrosine-based motif, YxxØ, is the best characterized of
the endocytic sorting signals that are recognized by and interact with
the clathrin-associated AP-2 complex (Ohno et al., 1995, 1996; Boll et
al., 1996; Rapoport et al., 1997). We have demonstrated that the
tyrosine-based sorting motif, YRSL, in the L1CD specifically interacts
with the µ2 chain of AP-2 in vitro and that L1 associates
with both AP-2 and AP180 in vivo. Because the interaction of
tyrosine-based sorting signals with AP-2 governs endocytosis of the
signal-bearing proteins (Kirchhausen et al., 1997; Marks et al., 1997),
the binding of L1 with AP-2 strongly suggests that L1 is endocytosed
via an AP-2 and clathrin-mediated pathway. This also has been
demonstrated in the present study by showing that L1 endocytosis is
blocked by dominant-negative dynamin, which is known specifically to
block clathrin-dependent endocytosis (van der Bliek et al., 1993; Damke
et al., 1994).
The YRSL sequence is conserved not only in mammalian L1 but also in
chick and zebrafish homologs of L1 (Hlavin and Lemmon, 1991; Tongiorgi
et al., 1995; Buchstaller et al., 1996). It also is conserved in other
members of the L1 subfamily, including neurofascin and NrCAM (Kayyem et
al., 1992; Volkmer et al., 1992), implying that the YRSL is a common
signal mediating endocytosis of L1 family CAMs. The L1CD contains three
other tyrosine residues (Hlavin and Lemmon, 1991), although none of
them constitutes a recognized sorting sequence that conforms to either
the YxxØ motif or another type of tyrosine-based motif, NPXY (Chen et
al., 1990; Kirchhausen et al., 1997; Marks et al., 1997). The YRSL
sequence in the L1CD is followed immediately by a cluster of acidic
amino acids containing Ser1181 that can be
phosphorylated by casein kinase II (CKII; see Fig. 1) (Wong et al.,
1996). This consensus motif for CKII phosphorylation also is conserved
in neurofascin and NrCAM. Several proteins localized to the trans-Golgi
network (TGN), such as furin and varicella-zoster virus glycoprotein I,
carry an acidic stretch with CKII phosphorylation sites, which is
situated C-terminal to tyrosine-based sorting signals. Internalization
of these proteins from the cell surface is dependent on both the CKII
phosphorylation sites and the tyrosine-based signals (Voorhees et al.,
1995; Alconada et al., 1996), implying that the phosphorylation of L1
by CKII also might play a role in L1 endocytosis.
The present study has shown that endocytosed L1FL
colocalizes with Tf and TfR in L1FL-transfected NIH-3T3
cells. The endocytic and recycling pathways of Tf and TfR are well
characterized (Dautry-Varsat, 1986). The TfR bears a tyrosine-based
signal YTRF in its cytoplasmic tail, which is recognized by the µ2
chain of AP-2 (Ohno et al., 1995). The Tf/TfR complex formed at the
cell surface is endocytosed through the clathrin-coated pits by
interacting with AP-2. Upon the uncoating of the endocytic vesicles and
dissociation of AP-2, the Tf/TfR complex is recycled to the cell
surface via early and recycling endosomes, but it does not enter
lysosomally directed pathways (Dautry-Varsat et al., 1983;
Dautry-Varsat, 1986). It is also possible that, after clathrin-mediated
endocytosis, L1FL is targeted to early and recycling
endosomes to be directed back to the cell surface, considering the
significant colocalization of endocytosed L1FL and Tf/TfR.
The failure of endocytosed
L1Y1176A and
L1RSLE to colocalize with Tf/TfR
suggests that these forms of L1 are internalized via a different
pathway from Tf/TfR uptake, for example, via clathrin-independent
endocytic pathways. These pathways, which include caveolae and
macropinocytosis, are known to exist in many types of mammalian cells
(Mellman, 1996). The observations that endocytosed L1FL,
but not L1Y1176A and
L1RSLE, colocalized with Tf/TfR
indicate that the YRSL sequence affects the endocytic traffic pathways
of L1, most likely by interacting with AP-2.
Endocytosis and recycling mechanisms are important not only for
ligand-transporting receptors, such as TfRs, but also for CAMs, such as
integrins, which are involved in cell motility. Cell migration is a
complex process requiring coordinated functions of cytoskeletal,
membrane, and adhesion systems. In migrating cells and in the growth
cone of extending axons, the backward flow of the actin cytoskeleton is
viewed as a force-generating system. When coupled to an extracellular
substrate via CAMs, the retrograde actin flow can generate force that
is required for the anterograde cell movement (Lin et al., 1994;
Mitchison and Cramer, 1996). CAMs, which have been translocated to the
rear by coupling to the backward actin flow, are internalized from the
cell surface and recycled to the leading edge (Lawson and Maxfield,
1995; Lauffenburger and Horwitz, 1996). The internalization of CAMs
provides a mechanism for creating a gradient of adhesive strength from
the front to the rear of migrating cells or axonal growth cones, which
is thought to be required for cell locomotion (Lauffenburger and
Horwitz, 1996).
The present work has demonstrated that L1, as visualized by 74-5H7,
colocalizes with Eps15 only at the rear of axonal growth cones. Because
Eps15 is present in an early phase of endocytosis (clathrin-coated
pits) (Tebar et al., 1996), the site-specific colocalization of L1 and
Eps15 strongly suggests that L1 is endocytosed preferentially at the
rear of growth cones. This was confirmed further by directly
visualizing endocytosed L1 in the growth cones. Because endocytosed L1
is restricted to the subregion of growth cones where L1 and Eps15
colocalize, it is most likely that the clathrin-mediated mechanism is
the major endocytic route for L1 in neurons. The observation that
74-5H7 labeled L1 in vesicular compartments also at the peripheral
domain of growth cones implies that L1 has been transported
anterogradely after endocytosis. The preferential endocytosis of L1 at
the rear of growth cones and the subsequent anterograde transport are
consistent with the general concept of CAM trafficking in migrating
cells. Further studies are needed to clarify what mechanism is involved
in regulating the L1 and AP-2 interaction to allow the site-specific
endocytosis of L1. It has been speculated that
Tyr1176 in the L1CD, which is a critical residue of
the tyrosine-based sorting signal YRSL, may be subject to
phosphorylation (Heiland et al., 1996). Considering that the critical
tyrosine has to be in a nonphosphorylated state for the signals to be
active in sorting (Boll et al., 1996; Ohno et al., 1996), the
phosphorylation of Tyr1176 may be involved in
regulating L1 endocytosis.
Another important implication of CAM endocytosis is that a cell could
regulate the surface expression of CAMs in response to its
extracellular environment. For example, integrin expression on the
neuronal cell surface is dynamically regulated by the extracellular ligand density, providing a mechanism by which neurons can maintain proper adhesive interactions over a broad range of ligand
concentrations (Condic and Letourneau, 1997). It is also likely that
extracellular ligand binding to L1 influences L1 endocytosis. Because
cis-interactions of L1 with other Ig superfamily members are
thought to initiate intracellular signaling in response to ligand
binding (Kamiguchi and Lemmon, 1997), it would be interesting to study
whether the cis-interactions could regulate L1
endocytosis.
In adult brain, L1 subfamily members are found in the hippocampus and
cerebellum (Brümmendorf and Rathjen, 1994), regions in which the
remodeling of synaptic connections is a critical and ongoing process.
Indeed, L1 has been implicated in hippocampal long-term potentiation
(Lüthl et al., 1994) and in spatial learning (Fransen et al.,
1998). Endocytosis of apCAM, a member of the Ig superfamily of CAMs, is
important during synaptic remodeling after conditioning in the gill
withdrawal reflex in Aplysia (Bailey et al., 1992; Mayford
et al., 1992). It is plausible that endocytosis of L1 also might play a
role in synaptic remodeling.
| |
FOOTNOTES |
Received Jan. 6, 1998; revised April 14, 1998; accepted April 27, 1998.
This work was supported by National Institutes of Health (NIH) Grants
EY-5285 and NS-34252, Vision Center Grant (P30 EY11373), and Program
Project Grant (PO1 NS32779) to V.L. and by NIH Grant GM 36548 to T.K.
We acknowledge the excellent technical assistance of Guanghui Cheng and
Zhenhua Miao. We are grateful to Dr. Sandra Lemmon and members of her
laboratory, especially Dr. Kristen Huang, who helped to introduce us to
the use of yeast two-hybrid technology. We also thank Drs. Juan
Bonifacino, Stephen Elledge, and Sandra Schmid for providing DNA
constructs and Drs. Cathleen Carlin, Susann Brady-Kalnay, and Sandra
Lemmon for helpful comments on this manuscript.
Correspondence should be addressed to Dr. Vance Lemmon, Department of
Neurosciences, Case Western Reserve University, 2109 Adelbert Road,
Cleveland, OH 44106-4975.
| |
REFERENCES |
-
Aberle H,
Schwartz H,
Kemler R
(1996)
Cadherin-catenin complex: protein interactions and their implications for cadherin function.
J Cell Biochem
61:514-523[Web of Science][Medline].
-
Ahle S,
Ungewickell E
(1986)
Purification and properties of a new clathrin assembly protein.
EMBO J
5:3143-3149[Web of Science][Medline].
-
Ahle S,
Ungewickell E
(1990)
Auxilin, a newly identified clathrin-associated protein in coated vesicles from bovine brain.
J Cell Biol
111:19-29[Abstract/Free Full Text].
-
Alconada A,
Bauer U,
Hoflack B
(1996)
A tyrosine-based motif and a casein kinase II phosphorylation site regulate the intracellular trafficking of the varicella-zoster virus glycoprotein I, a protein localized in the trans-Golgi network.
EMBO J
15:6096-6110[Web of Science][Medline].
-
Bailey CH,
Chen M,
Keller F,
Kandel ER
(1992)
Serotonin-mediated endocytosis of apCAM: an early step of learning-related synaptic growth in Aplysia.
Science
256:645-649[Abstract/Free Full Text].
-
Boll W,
Ohno H,
Songyang Z,
Rapoport I,
Cantley LC,
Bonifacino JS,
Kirchhausen T
(1996)
Sequence requirements for the recognition of tyrosine-based endocytic signals by clathrin AP-2 complexes.
EMBO J
15:5789-5795[Web of Science][Medline].
-
Brümmendorf T,
Rathjen FG
(1994)
Cell adhesion molecules. 1. Immunoglobulin superfamily.
Protein Profile
1:951-1058[Web of Science][Medline].
-
Buchstaller A,
Kunz S,
Berger P,
Kunz B,
Ziegler U,
Rader C,
Sonderegger P
(1996)
Cell adhesion molecules NgCAM and axonin-1 form heterodimers in the neuronal membrane and cooperate in neurite outgrowth promotion.
J Cell Biol
135:1593-1607[Abstract/Free Full Text].
-
Chen W-J,
Goldstein JL,
Brown MS
(1990)
NPXY, a sequence often found in cytoplasmic tails, is required for coated pit-mediated internalization of the low density lipoprotein receptor.
J Biol Chem
265:3116-3123[Abstract/Free Full Text].
-
Cohen NR,
Taylor JSH,
Scott LB,
Guillery RW,
Soriano P,
Furley AJW
(1997)
Errors in corticospinal axon guidance in mice lacking the neural cell adhesion molecule L1.
Curr Biol
8:26-33.
-
Condic ML,
Letourneau PC
(1997)
Ligand-induced changes in integrin expression regulate neuronal adhesion and neurite outgrowth.
Nature
389:852-856[Medline].
-
Cupers P,
ter Haar E,
Boll W,
Kirchhausen T
(1997)
Parallel dimers and anti-parallel tetramers formed by epidermal growth factor receptor pathway substrate clone 15 (Eps15).
J Biol Chem
272:33430-33434[Abstract/Free Full Text].
-
Dahme M,
Bartsch U,
Martini R,
Anliker B,
Schachner M,
Mantei N
(1997)
Disruption of the mouse L1 gene leads to malformations of the nervous system.
Nat Genet
17:346-349[Web of Science][Medline].
-
Damke H,
Baba T,
Warnock DE,
Schmid SL
(1994)
Induction of mutant dynamin specifically blocks endocytic coated vesicle formation.
J Cell Biol
127:915-934[Abstract/Free Full Text].
-
Dautry-Varsat A
(1986)
Receptor-mediated endocytosis: the intracellular journey of transferrin and its receptor.
Biochimie
68:375-381[Medline].
-
Dautry-Varsat A,
Ciechanover A,
Lodish HF
(1983)
pH and the recycling of transferrin during receptor-mediated endocytosis.
Proc Natl Acad Sci USA
80:2258-2262[Abstract/Free Full Text].
-
Ebnet K,
Kaldjian EP,
Anderson AO,
Shaw S
(1996)
Orchestrated information transfer underlying leukocyte endothelial interactions.
Annu Rev Immunol
14:155-177[Web of Science][Medline].
-
Fields RD,
Itoh K
(1996)
Neural cell adhesion molecules in activity-dependent development and synaptic plasticity.
Trends Neurosci
19:473-480[Web of Science][Medline].
-
Fransen E,
D'Hooge R,
Van Camp G,
Verhoye M,
Sijbers J,
Reyniers E,
Soriano P,
Kamiguchi H,
Willemsen R,
Koekkoek SKE,
De Zeeuw CI,
De Deyn PP,
Van der Linden A,
Lemmon V,
Kooy RF,
Willems PJ
(1998)
L1 knock-out mice show dilated ventricles, vermis hypoplasia, and impaired exploration patterns.
Hum Mol Genet
7:999-1009[Abstract/Free Full Text].
-
Gallusser A,
Kirchhausen T
(1993)
The 1 and 2 subunits of the AP complexes are the clathrin coat assembly components.
EMBO J
12:5237-5244[Web of Science][Medline].
-
Golemis EA,
Gyuris J,
Brent R
(1996)
Interaction trap/two-hybrid system to identify interacting proteins.
In: Current protocols in molecular biology (Ausubel FM,
Brent R,
Kingston RE,
Moore DD,
Seidman JG,
Smith JA,
Struhl K,
eds), pp 20.1.1-20.1.28. New York: Wiley.
-
Heiland PC,
Hertlein B,
Traub O,
Griffith LS,
Schmitz B
(1996)
The neural adhesion molecule L1 is phosphorylated on tyrosine and serine residues.
NeuroReport
7:2675-2678.[Web of Science][Medline]
-
Hinshaw JE,
Schmid SL
(1995)
Dynamin self-assembles into rings suggesting a mechanism for coated vesicle budding.
Nature
374:190-192[Medline].
-
Hlavin ML,
Lemmon V
(1991)
Molecular structure and functional testing of human L1CAM: an interspecies comparison.
Genomics
11:416-423[Web of Science][Medline].
-
Hortsch M
(1996)
The L1 family of neural cell adhesion molecules: old proteins performing new tricks.
Neuron
17:587-593[Web of Science][Medline].
-
Hortsch M,
Wang Y,
Marikar Y,
Bieber AJ
(1995)
The cytoplasmic domain of the Drosophila cell adhesion molecule neuroglian is not essential for its homophilic adhesive properties in S2 cells.
J Biol Chem
270:18809-18817[Abstract/Free Full Text].
-
Kamiguchi H,
Lemmon V
(1997)
Neural cell adhesion molecule L1: signaling pathways and growth cone motility.
J Neurosci Res
49:1-8[Web of Science][Medline].
-
Kamiguchi H,
Lemmon V
(1998)
A neuronal form of the cell adhesion molecule L1 contains a tyrosine-based signal required for sorting to the axonal growth cone.
J Neurosci
18:3749-3756[Abstract/Free Full Text].
-
Kamiguchi H,
Hlavin ML,
Yamasaki M,
Lemmon V
(1998)
Adhesion molecules and inherited diseases of the human nervous system.
Annu Rev Neurosci
21:97-125[Web of Science][Medline].
-
Kayyem JF,
Roman JM,
de la Rosa EJ,
Schwarz U,
Dreyer WJ
(1992)
Bravo/Nr-CAM is closely related to the cell adhesion molecules L1 and Ng-CAM and has a similar heterodimer structure.
J Cell Biol
118:1259-1270[Abstract/Free Full Text].
-
Kirchhausen T,
Bonifacino JS,
Riezman H
(1997)
Linking cargo to vesicle formation: receptor tail interactions with coat proteins.
Curr Opin Cell Biol
9:488-495[Web of Science][Medline].
-
Klausner RD,
Van Renswoude J,
Ashwell G,
Kempf C,
Schechter AN,
Dean A,
Bridges KR
(1983)
Receptor-mediated endocytosis of transferrin in K562 cells.
J Biol Chem
258:4715-4724[Abstract/Free Full Text].
-
Kolanus W,
Seed B
(1997)
Integrins and inside-out signal transduction: converging signals from PKC and PIP3.
Curr Opin Cell Biol
9:725-731[Web of Science][Medline].
-
Lauffenburger DA,
Horwitz AF
(1996)
Cell migration: a physically integrated molecular process.
Cell
84:359-369[Web of Science][Medline].
-
Lawson MA,
Maxfield FR
(1995)
Ca2+- and calcineurin-dependent recycling of an integrin to the front of migrating neutrophils.
Nature
377:75-79[Medline].
-
Lemmon V,
McLoon S
(1986)
The appearance of an L1-like molecule in the chick primary visual pathway.
J Neurosci
6:2987-2994[Abstract].
-
Lemmon V,
Farr K,
Lagenaur C
(1989)
L1-mediated axon outgrowth occurs via a homophilic binding mechanism.
Neuron
2:1597-1603[Web of Science][Medline].
-
Lin CH,
Thompson CA,
Forscher P
(1994)
Cytoskeletal reorganization underlying growth cone motility.
Curr Opin Neurobiol
4:640-647[Medline].
-
Luther PW,
Bloch RJ
(1989)
Formaldehyde-amine fixatives for immunocytochemistry of cultured Xenopus myocytes.
J Histochem Cytochem
37:75-82[Abstract].
-
Lüthl A,
Laurent JP,
Figurov A,
Muller D,
Schachner M
(1994)
Hippocampal long-term potentiation and neural cell adhesion molecule L1 and NCAM.
Nature
372:777-779[Medline].
-
Marks MS,
Ohno H,
Kirchhausen T,
Bonifacino JS
(1997)
Protein sorting by tyrosine-based signals: adapting to the Ys and wherefores.
Trends Cell Biol
7:124-128.[Medline]
-
Mayford M,
Barzilai A,
Keller F,
Schacher S,
Kandel ER
(1992)
Modulation of an NCAM-related adhesion molecule with long-term synaptic plasticity in Aplysia.
Science
256:638-644[Abstract/Free Full Text].
-
Mellman I
(1996)
Endocytosis and molecular sorting.
Annu Rev Cell Dev Biol
12:575-625[Web of Science][Medline].
-
Mitchison TJ,
Cramer LP
(1996)
Actin-based cell motility and cell locomotion.
Cell
84:371-379[Web of Science][Medline].
-
Miura M,
Kobayashi M,
Asou H,
Uyemura K
(1991)
Molecular cloning of cDNA encoding the rat neural cell adhesion molecule L1
 two L1 isoforms in the cytoplasmic region are produced by differential splicing.
FEBS Lett
289:91-95[Web of Science][Medline]. -
Nelson KK,
Lemmon SK
(1993)
Suppressors of clathrin deficiency: overexpression of ubiquitin rescues lethal strains of clathrin-deficient Saccharomyces cerevisiae.
Mol Cell Biol
13:521-532[Abstract/Free Full Text].
-
Ohno H,
Stewart J,
Fournier MC,
Bosshart H,
Rhee I,
Miyatake S,
Saito T,
Gallusser A,
Kirchhausen T,
Bonifacino JS
(1995)
Interaction of tyrosine-based sorting signals with clathrin-associated proteins.
Science
269:1872-1875[Abstract/Free Full Text].
-
Ohno H,
Fournier MC,
Poy G,
Bonifacino JS
(1996)
Structural determinants of interaction of tyrosine-based sorting signals with the adaptor medium chains.
J Biol Chem
271:29009-29015[Abstract/Free Full Text].
-
Palecek SP,
Schmidt CE,
Lauffenburger DA,
Horwitz AF
(1996)
Integrin dynamics on the tail region of migrating fibroblasts.
J Cell Sci
109:941-952[Abstract].
-
Rapoport I,
Miyazaki M,
Boll W,
Duckworth B,
Cantley LC,
Shoelson S,
Kirchhausen T
(1997)
Regulatory interactions in the recognition of endocytic sorting signals by AP-2 complexes.
EMBO J
16:2240-2250[Web of Science][Medline].
-
Rutishauser U,
Landmesser L
(1996)
Polysialic acid in the vertebrate nervous system: a promoter of plasticity in cell-cell interactions.
Trends Neurosci
19:422-427[Web of Science][Medline].
-
Takeda Y,
Asou H,
Murakami Y,
Miura M,
Kobayashi M,
Uyemura K
(1996)
A nonneuronal isoform of cell adhesion molecule L1: tissue-specific expression and functional analysis.
J Neurochem
66:2338-2349[Web of Science][Medline].
-
Takei K,
McPherson PS,
Schmid SL,
De Camilli P
(1995)
Tubular membrane invaginations coated by dynamin rings are induced by GTP-
 S in nerve terminals.
Nature
374:186-190[Medline]. -
Tebar F,
Sorkina T,
Sorkin A,
Ericsson M,
Kirchhausen T
(1996)
Eps15 is a component of clathrin-coated pits and vesicles and is located at the rim of coated pits.
J Biol Chem
271:28727-28730[Abstract/Free Full Text].
-
Tongiorgi E,
Bernhardt RR,
Schachner M
(1995)
Zebrafish neurons express two L1-related molecules during early axonogenesis.
J Neurosci Res
42:547-561[Web of Science][Medline].
-
Trowbridge IS,
Collawn JF,
Hopkins CR
(1993)
Signal-dependent membrane protein trafficking in the endocytic pathway.
Annu Rev Cell Biol
9:129-161[Web of Science].
-
van Delft S,
Schumacher C,
Hage W,
Verkleij AJ,
van Bergen en Henegouwen PMP
(1997)
Association and colocalization of Eps15 with adaptor protein-2 and clathrin.
J Cell Biol
136:811-821[Abstract/Free Full Text].
-
van der Bliek AM,
Redelmeier TE,
Damke H,
Tisdale EJ,
Meyerowitz EM,
Schmid SL
(1993)
Mutations in human dynamin block an intermediate stage in coated vesicle formation.
J Cell Biol
122:553-563[Abstract/Free Full Text].
-
Volkmer H,
Hassel B,
Wolff JM,
Frank R,
Rathjen FG
(1992)
Structure of the axonal surface recognition molecule neurofascin and its relationship to a neural subgroup of the immunoglobulin superfamily.
J Cell Biol
118:149-161[Abstract/Free Full Text].
-
Voorhees P,
Deignan E,
van Donselaar E,
Humphrey J,
Marks MS,
Peters PJ,
Bonifacino JS
(1995)
An acidic sequence within the cytoplasmic domain of furin functions as a determinant of trans-Golgi network localization and internalization from the cell surface.
EMBO J
14:4961-4975[Web of Science][Medline].
-
Weber C,
Alon R,
Moser B,
Springer TA
(1996)
Sequential regulation of 41 and 51 integrin avidity by CC chemokines in monocytes: implications for transendothelial chemotaxis.
J Cell Biol
134:1063-1073[Abstract/Free Full Text].
-
Wong EV,
Cheng G,
Payne HR,
Lemmon V
(1995)
The cytoplasmic domain of the cell adhesion molecule L1 is not required for homophilic adhesion.
Neurosci Lett
200:155-158[Web of Science][Medline].
-
Wong EV,
Schaefer AW,
Landreth G,
Lemmon V
(1996)
Casein kinase II phosphorylates the neural cell adhesion molecule L1.
J Neurochem
66:779-786[Web of Science][Medline].
Copyright © 1998 Society for Neuroscience 0270-6474/98/18145311-11$05.00/0
This article has been cited by other articles:
|
|
|
|
 
C. Mollinari, L. Ricci-Vitiani, M. Pieri, C. Lucantoni, A. M. Rinaldi, M. Racaniello, R. De Maria, C. Zona, R. Pallini, D. Merlo, et al.
Downregulation of thymosin {beta}4 in neural progenitor grafts promotes spinal cord regeneration
J. Cell Sci.,
November 15, 2009;
122(22):
4195 - 4207.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
C. C. Yap, R. L. Nokes, D. Wisco, E. Anderson, H. Folsch, and B. Winckler
Pathway selection to the axon depends on multiple targeting signals in NgCAM
J. Cell Sci.,
May 1, 2008;
121(9):
1514 - 1525.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Buhusi, M. C. Schlatter, G. P. Demyanenko, R. Thresher, and P. F. Maness
L1 Interaction with Ankyrin Regulates Mediolateral Topography in the Retinocollicular Projection
J. Neurosci.,
January 2, 2008;
28(1):
177 - 188.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
C. Dequidt, L. Danglot, P. Alberts, T. Galli, D. Choquet, and O. Thoumine
Fast Turnover of L1 Adhesions in Neuronal Growth Cones Involving Both Surface Diffusion and Exo/Endocytosis of L1 Molecules
Mol. Biol. Cell,
August 1, 2007;
18(8):
3131 - 3143.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
T. Boiko, M. Vakulenko, H. Ewers, C. C. Yap, C. Norden, and B. Winckler
Ankyrin-Dependent and -Independent Mechanisms Orchestrate Axonal Compartmentalization of L1 Family Members Neurofascin and L1/Neuron-Glia Cell Adhesion Molecule
J. Neurosci.,
January 17, 2007;
27(3):
590 - 603.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
K. Knogler, J. Grunberg, K. Zimmermann, S. Cohrs, M. Honer, S. Ametamey, P. Altevogt, M. Fogel, P. A. Schubiger, and I. Novak-Hofer
Copper-67 Radioimmunotherapy and Growth Inhibition by Anti-L1-Cell Adhesion Molecule Monoclonal Antibodies in a Therapy Model of Ovarian Cancer Metastasis
Clin. Cancer Res.,
January 15, 2007;
13(2):
603 - 611.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. D. Whittard, T. Sakurai, M. R. Cassella, M. Gazdoiu, and D. P. Felsenfeld
MAP Kinase Pathway-dependent Phosphorylation of the L1-CAM Ankyrin Binding Site Regulates Neuronal Growth
Mol. Biol. Cell,
June 1, 2006;
17(6):
2696 - 2706.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
E. Anderson, S. Maday, J. Sfakianos, M. Hull, B. Winckler, D. Sheff, H. Folsch, and I. Mellman
Transcytosis of NgCAM in epithelial cells reflects differential signal recognition on the endocytic and secretory pathways
J. Cell Biol.,
August 15, 2005;
170(4):
595 - 605.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
V. Proux-Gillardeaux, J. Gavard, T. Irinopoulou, R.-M. Mege, and T. Galli
Tetanus neurotoxin-mediated cleavage of cellubrevin impairs epithelial cell migration and integrin-dependent cell adhesion
PNAS,
May 3, 2005;
102(18):
6362 - 6367.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
T. Piazza, E. Cha, I. Bongarzone, S. Canevari, A. Bolognesi, L. Polito, A. Bargellesi, F. Sassi, S. Ferrini, and M. Fabbi
Internalization and recycling of ALCAM/CD166 detected by a fully human single-chain recombinant antibody
J. Cell Sci.,
April 1, 2005;
118(7):
1515 - 1525.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
L. Cheng, K. Itoh, and V. Lemmon
L1-Mediated Branching Is Regulated by Two Ezrin-Radixin-Moesin (ERM)-Binding Sites, the RSLE Region and a Novel Juxtamembrane ERM-Binding Region
J. Neurosci.,
January 12, 2005;
25(2):
395 - 403.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. D. Malhotra, V. Thyagarajan, C. Chen, and L. L. Isom
Tyrosine-phosphorylated and Nonphosphorylated Sodium Channel {beta}1 Subunits Are Differentially Localized in Cardiac Myocytes
J. Biol. Chem.,
September 24, 2004;
279(39):
40748 - 40754.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
V. J. Tom, M. P. Steinmetz, J. H. Miller, C. M. Doller, and J. Silver
Studies on the Development and Behavior of the Dystrophic Growth Cone, the Hallmark of Regeneration Failure, in an In Vitro Model of the Glial Scar and after Spinal Cord Injury
J. Neurosci.,
July 21, 2004;
24(29):
6531 - 6539.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
S. Silletti, M. Yebra, B. Perez, V. Cirulli, M. McMahon, and A. M. P. Montgomery
Extracellular Signal-regulated Kinase (ERK)-dependent Gene Expression Contributes to L1 Cell Adhesion Molecule-dependent Motility and Invasion
J. Biol. Chem.,
July 9, 2004;
279(28):
28880 - 28888.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
D. P. McEwen, L. S. Meadows, C. Chen, V. Thyagarajan, and L. L. Isom
Sodium Channel {beta}1 Subunit-mediated Modulation of Nav1.2 Currents and Cell Surface Density Is Dependent on Interactions with Contactin and Ankyrin
J. Biol. Chem.,
April 16, 2004;
279(16):
16044 - 16049.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
I. Beitia Ortiz de Zarate, K. Kaelin, and F. Rozenberg
Effects of Mutations in the Cytoplasmic Domain of Herpes Simplex Virus Type 1 Glycoprotein B on Intracellular Transport and Infectivity
J. Virol.,
February 1, 2004;
78(3):
1540 - 1551.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
P. Alberts, R. Rudge, I. Hinners, A. Muzerelle, S. Martinez-Arca, T. Irinopoulou, V. Marthiens, S. Tooze, F. Rathjen, P. Gaspar, et al.
Cross Talk between Tetanus Neurotoxin-insensitive Vesicle-associated Membrane Protein-mediated Transport and L1-mediated Adhesion
Mol. Biol. Cell,
October 1, 2003;
14(10):
4207 - 4220.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
D. Wisco, E. D. Anderson, M. C. Chang, C. Norden, T. Boiko, H. Folsch, and B. Winckler
Uncovering multiple axonal targeting pathways in hippocampal neurons
J. Cell Biol.,
September 29, 2003;
162(7):
1317 - 1328.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Buhusi, B. R. Midkiff, A. M. Gates, M. Richter, M. Schachner, and P. F. Maness
Close Homolog of L1 Is an Enhancer of Integrin-mediated Cell Migration
J. Biol. Chem.,
June 27, 2003;
278(27):
25024 - 25031.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
D. Herring, R. Huang, M. Singh, L. C. Robinson, G. H. Dillon, and N. J. Leidenheimer
Constitutive GABAA Receptor Endocytosis Is Dynamin-mediated and Dependent on a Dileucine AP2 Adaptin-binding Motif within the {beta}2 Subunit of the Receptor
J. Biol. Chem.,
June 20, 2003;
278(26):
24046 - 24052.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
J. Z. Rappoport and S. M. Simon
Real-time analysis of clathrin-mediated endocytosis during cell migration
J. Cell Sci.,
March 1, 2003;
116(5):
847 - 855.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
T. C. Dickson, C. D. Mintz, D. L. Benson, and S. R.J. Salton
Functional binding interaction identified between the axonal CAM L1 and members of the ERM family
J. Cell Biol.,
June 24, 2002;
157(7):
1105 - 1112.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. W. Schaefer, Y. Kamei, H. Kamiguchi, E. V. Wong, I. Rapoport, T. Kirchhausen, C. M. Beach, G. Landreth, S. K. Lemmon, and V. Lemmon
L1 endocytosis is controlled by a phosphorylation-dephosphorylation cycle stimulated by outside-in signaling by L1
J. Cell Biol.,
June 24, 2002;
157(7):
1223 - 1232.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
K. Thelen, V. Kedar, A. K. Panicker, R.-S. Schmid, B. R. Midkiff, and P. F. Maness
The Neural Cell Adhesion Molecule L1 Potentiates Integrin-Dependent Cell Migration to Extracellular Matrix Proteins
J. Neurosci.,
June 15, 2002;
22(12):
4918 - 4931.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
H. Kamiguchi and F. Yoshihara
The Role of Endocytic L1 Trafficking in Polarized Adhesion and Migration of Nerve Growth Cones
J. Neurosci.,
December 1, 2001;
21(23):
9194 - 9203.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
F. Bouzioukh, F. Tell, A. Jean, and G. Rougon
NMDA Receptor and Nitric Oxide Synthase Activation Regulate Polysialylated Neural Cell Adhesion Molecule Expression in Adult Brainstem Synapses
J. Neurosci.,
July 1, 2001;
21(13):
4721 - 4730.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
L. K. Needham, K. Thelen, and P. F. Maness
Cytoplasmic Domain Mutations of the L1 Cell Adhesion Molecule Reduce L1-Ankyrin Interactions
J. Neurosci.,
March 1, 2001;
21(5):
1490 - 1500.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
R.-S. Schmid, W. M. Pruitt, and P. F. Maness
A MAP Kinase-Signaling Pathway Mediates Neurite Outgrowth on L1 and Requires Src-Dependent Endocytosis
J. Neurosci.,
June 1, 2000;
20(11):
4177 - 4188.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
H. Kamiguchi and V. Lemmon
Recycling of the Cell Adhesion Molecule L1 in Axonal Growth Cones
J. Neurosci.,
May 15, 2000;
20(10):
3676 - 3686.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
S. Kenwrick, A. Watkins, and E. D. Angelis
Neural cell recognition molecule L1: relating biological complexity to human disease mutations
Hum. Mol. Genet.,
April 1, 2000;
9(6):
879 - 886.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
A. W. Schaefer, H. Kamiguchi, E. V. Wong, C. M. Beach, G. Landreth, and V. Lemmon
Activation of the MAPK Signal Cascade by the Neural Cell Adhesion Molecule L1 Requires L1 Internalization
J. Biol. Chem.,
December 31, 1999;
274(53):
37965 - 37973.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
T. Esch, V. Lemmon, and G. Banker
Local Presentation of Substrate Molecules Directs Axon Specification by Cultured Hippocampal Neurons
J. Neurosci.,
August 1, 1999;
19(15):
6417 - 6426.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
C. F. Bearer, A. R. Swick, M. A. O'Riordan, and G. Cheng
Ethanol inhibits L1-mediated neurite outgrowth in postnatal rat cerebellar granule cells.
J. Biol. Chem.,
July 9, 1999;
274(28):
20046 - 20046.
[Full Text]
[PDF]
|
|
|
|
|
|
|
C. F. Bearer, A. R. Swick, M. A. O'Riordan, and G. Cheng
Ethanol Inhibits L1-mediated Neurite Outgrowth in Postnatal Rat Cerebellar Granule Cells
J. Biol. Chem.,
May 7, 1999;
274(19):
13264 - 13270.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
C Faivre-Sarrailh, J Falk, E Pollerberg, M Schachner, and G Rougon
NrCAM, cerebellar granule cell receptor for the neuronal adhesion molecule F3, displays an actin-dependent mobility in growth cones
J. Cell Sci.,
January 9, 1999;
112(18):
3015 - 3027.
[Abstract]
[PDF]
|
|
|
|
|
|
|
L. Roth, P Bormann, A Bonnet, and E Reinhard
beta-thymosin is required for axonal tract formation in developing zebrafish brain
Development,
January 4, 1999;
126(7):
1365 - 1374.
[Abstract]
[PDF]
|
|
|
|
|
|
|
K. E. Long, H. Asou, M. D. Snider, and V. Lemmon
The Role of Endocytosis in Regulating L1-mediated Adhesion
J. Biol. Chem.,
January 5, 2001;
276(2):
1285 - 1290.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
M. Koroll, F. G. Rathjen, and H. Volkmer
The Neural Cell Recognition Molecule Neurofascin Interacts with Syntenin-1 but Not with Syntenin-2, Both of Which Reveal Self-associating Activity
J. Biol. Chem.,
March 30, 2001;
276(14):
10646 - 10654.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
|
|
E. De Angelis, T. Brummendorf, L. Cheng, V. Lemmon, and S. Kenwrick
Alternative Use of a Mini Exon of the L1 Gene Affects L1 Binding to Neural Ligands
J. Biol. Chem.,
August 24, 2001;
276(35):
32738 - 32742.
[Abstract]
[Full Text]
[PDF]
|
|
|
|
|
Top
Abstract
Introduction
