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J Biol Chem, Vol. 275, Issue 5, 3288-3295, February 4, 2000
From Clathrin-coated pit (CCP) formation occurs as a
result of the targeting and assembly of cytosolic coat proteins, mainly
the plasma membrane clathrin-associated protein complex (AP-2) and clathrin, to the intracellular face of the plasma membrane. In the
present study, the mechanisms by which Eps15, an AP-2-binding protein,
is targeted to CCPs was analyzed by following the intracellular localization of Eps15 mutants fused to the green fluorescent protein. Our previous results indicated that the N-terminal Eps15
homology (EH) domains are required for CCP targeting. We
now show that EH domains are, however, not sufficient for targeting to
CCPs. Similarly, neither the central coiled-coil nor the C-terminal AP-2 binding domains were able to address green fluorescent protein to
CCPs. Thus, targeting of Eps15 to CCPs likely results from the
collaboration between EH domains and another domain of the protein. An
Eps15 mutant lacking the coiled-coil domain localized to CCPs showing
that Eps15 dimerization is not strictly required. In contrast, Eps15
mutants lacking all AP-2 binding sites showed a dramatic decrease in
plasma membrane staining, showing that AP-2 binding sites, together
with EH domains, play an important role in targeting Eps15 into CCPs.
Finally, the effect of the Eps15 mutants on
clathrin-dependent endocytosis was tested by both
immunofluorescence and flow cytometry. The results obtained showed that
inhibition of transferrin uptake was observed only with mutants able to
interfere with CCP assembly.
Clathrin-coated vesicle formation represents the initial step of
the major pathway for receptor-mediated endocytosis. The known roles of
AP-2,1 clathrin and dynamin
in this process are as follows. AP-2 is believed to drive clathrin
assembly at the plasma membrane and binds to tyrosine-based
internalization signals, playing a central role in both formation and
function of clathrin-coated pits (CCPs); clathrin gives an organizing
framework to the pit; and the dynamin GTPase activity is required for
membrane fusion events leading to coated vesicle formation (1-5).
The mechanisms by which these soluble proteins are targeted to the
plasma membrane to form an organized clathrin coat have been
extensively studied. Targeting of AP-2 complexes is mediated by its
The Eps15 protein is constitutively and ubiquitously associated with
AP-2 (22). Recent data obtained both in vivo and in a
perforated cell assay showed that Eps15 is required for the early steps
of clathrin-dependent endocytosis (23, 24). The fact that
Eps15 is not found in coated vesicles (25) suggested a coated
pit-restricted function. Results showing that the Cells and Antibodies--
HeLa cells (ATCC, Manassas, VA) were
grown in Dulbecco's modified Eagle's medium supplemented with 10%
fetal calf serum, 2 mM L-glutamine, penicillin,
and streptomycin (Life Technologies, Inc.). The mouse monoclonal
antibodies AP.6 (anti-AP-2 (35)) and OKT9 (anti-human transferrin
receptor (Tf-R)) were obtained from ATCC. Texas Red-conjugated goat
anti-mouse immunoglobulins were obtained from Molecular Probes (Eugene,
OR), Cy5-conjugated goat anti-mouse immunoglobulins were from Amersham
Pharmacia Biotech, and phycoerythrin-conjugated F(ab')2 fragment goat
anti-mouse IgG was from Immunotech (Marseille, France).
Generation of the GFP-Eps15 Constructs--
The cDNA of
human Eps15 subcloned in pBluescript® II KS (Stratagene, La Jolla, CA)
was obtained in the laboratory (22) and used as a template to generate
the different cDNA fragments used in this study. The Eps15
constructs encoding each structural domain subcloned in the PGEX5.1
vector (Amersham Pharmacia Biotech) and the EH deleted mutant
E Transfections, Immunofluorescence, and
Endocytosis--
Subconfluent HeLa cells were used for transient
expression of the different constructs. Transfections were performed
using the CalPhos Maximizer transfection kit from
CLONTECH.
For immunofluorescence studies, transfected HeLa cells were grown on
coverslips and used the day after transfection. The cells were washed
in PBS and fixed in 3.7% paraformaldehyde and 0.03 M
sucrose for 30 min at 4 °C. The cells were then washed once in PBS
and, after quenching for 10 min in 50 mM NH4Cl
in PBS, washed again in PBS supplemented with 1 mg/ml bovine serum
albumin (BSA). The cells were then incubated with the AP.6 antibody in permeabilization buffer (PBS with 1 mg/ml BSA and 0.05% saponin) for
45 min at room temperature. After two washes in the permeabilization buffer, the presence of antibodies was revealed by incubating the cells
for 45 min at room temperature in permeabilization buffer containing
labeled secondary antibody. After two washes in permeabilization buffer
and one in PBS, the cells were mounted on microscope slides in 100 mg/ml Mowiol (Calbiochem), 25% glycerol (v/v), and 100 mM
Tris-HCl, pH 8.5. To wash out cytosolic GFP constructs, the cells were
briefly permeabilized before fixation with a 2-5-min incubation with
0.03% saponin in cytosolic buffer (100 mM potassium acetate, 1 mM MgCl2, 20 mM Hepes)
at 4 °C. The cells were then washed twice in cytosolic buffer and
processed for immunofluorescence as described above. For surface
staining, transfected cells were incubated with antibodies in PBS, 1 mg/ml BSA at 4 °C.
Human transferrin (Tf) was conjugated to Cy3 dye using the CyDye
FluoroLink reactive dye kit from Amersham Pharmacia Biotech following
the manufacturer's instructions. Endocytosis of Cy3-conjugated Tf was
performed on subconfluent HeLa cells grown on coverslips 1 day after
transfection. The cells were first incubated for 20 min at 37 °C in
Dulbecco's modified Eagle's medium and 20 mM Hepes, pH
7.2, to eliminate receptor-bound Tf and then incubated in Dulbecco's modified Eagle's medium, 20 mM Hepes, pH 7.2, and 1 mg/ml
BSA containing 100 nM Cy3-conjugated Tf. After incubation
at 37 °C for 15 min, the cells were rapidly cooled to 4 °C,
washed twice in cold PBS, and then fixed as described above. The
samples were examined under an epifluorescence microscope (Zeiss,
Oberkochen, Germany) attached to a cooled CCD camera (Photometrics,
Tucson, AZ).
Quantification of Cell Surface Transferrin Receptors--
Cell
surface Tf-Rs were quantified by flow cytometry. HeLa cells were
detached from culture plates 1 day after transfection using a Costar
cell lifter. Cells were washed twice in PBS, 1 mg/ml BSA and then
incubated at 4 °C for 45 min with anti-Tf-R antibody OKT9 at
saturating concentrations in PBS 1 mg/ml BSA. The cells were then
washed twice in PBS 1 mg/ml BSA and incubated at 4 °C for 45 min in
PBS 1 mg/ml BSA with a phycoerythrin-conjugated goat anti-mouse IgG.
The cells were then washed twice in PBS 1 mg/ml BSA, and the levels of
expression of both GFP and Tf-R on the cell surface were assessed using
a FACSCAN (Becton Dickinson, San Jose, CA). Data were analyzed using
the CELLQuest program (Becton Dickinson).
Endogenous Eps15 is constitutively found in CCPs (18, 36).
Addition of the GFP to its N terminus does not modify its intracellular localization (8, 24), with the resulting GFP-Eps15 construct showing a
punctate staining at the plasma membrane that colocalizes with AP-2
(Fig. 2, a, b, and insets). In this
study, the GFP fusion system was used to map the domains of Eps15
involved in its targeting to CCPs. The different mutants derived from
Eps15 (see Fig. 6) were fused to GFP, the resulting constructs were
transiently transfected into HeLa cells, and their intracellular
distribution was compared with that of AP-2.
The results obtained in our previous study showed that EH domains are
required for CCP targeting of Ep15. Indeed, an Eps15 construct lacking
the second and third EH domains showed a diffuse cytosolic staining
(8). The putative role of EH domains as a sufficient coated pit
targeting signal was first tested. As shown in Fig.
1a, a GFP construct encoding
EH domains (DI) presented a diffuse intracellular staining, suggesting
that the DI construct was not targeted to CCP. This was confirmed by
its lack of colocalization with AP-2 at the plasma membrane (Fig. 1,
a, b, and insets), showing that EH
domains were unable to specifically target GFP to CCPs. From these and
previous results (8) it can be concluded that EH domains are required
but not sufficient for CCP targeting.
The central coiled-coil and C-terminal AP-2 binding domains, DII and
DIII constructs, respectively, were then tested for their capacity to
bring GFP to CCPs. The DII construct was diffusely distributed in
cytosol and did not colocalize with AP-2 at the plasma membrane (Fig.
1, c, d, and insets). A similar
cytosolic staining was observed with the DIII construct (Fig.
1e). However, expression of the DIII construct, previously
shown to inhibit clathrin-dependent endocytosis (24),
induced a mislocalization of AP-2 complexes. Cells expressing DIII
showed less AP-2 dots at the plasma membrane and an increase in
cytosolic staining compared with neighboring untransfected cells (Fig.
1f, indicated by arrows). These results are
reminiscent of those obtained with the E The fact that EH domains are necessary but not sufficient for coated
pit targeting suggests the involvement of another domain(s) in this
process. We first investigated the role of the C-terminal domain.
Indeed, the C-terminal domain of Eps15 contains both AP-2 binding sites
and a proline-rich region. The proline-rich region is found between
amino acids 768 and 849 and contains a PALPPK (768/774) sequence that
binds to SH3 domain-containing proteins (37, 38). Interestingly, a
proline-rich domain is responsible for the targeting of dynamin to CCPs
(16) through interaction with the SH3 domain of amphiphysin (39). Such
a mechanism could therefore also be involved in Eps15 targeting. Eps15
constructs lacking either the 849-896 (E
Mapping of Eps15 Domains Involved in Its Targeting to
Clathrin-coated Pits*
§¶,
,, and INSERM E9925, Faculté Necker-Enfants
Malades, 156 rue de Vaugirard, 75730 Paris, and
§ Unité de Biologie des Interactions Cellulaires,
URA-CNRS 1960, Institut Pasteur, 25 rue de Dr. Roux, 75724 Paris, Cedex
15, France
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-adaptin subunit. Studies of chimeras in which equivalent domains of
-adaptin from AP-2 and 
-adaptin from AP-1 were exchanged allowed
the identification of a CCP targeting signal within a 200-amino acid
region of the N-terminal "head" or "trunk" domain of
-adaptin. These studies also established a role for the C-terminal "ear" domain of -adaptin (6, 7), a result confirmed by recent
data showing efficient targeting of a GFP-ear construct to CCP (8).
Furthermore, the -adaptin N-terminal domain also contains a
phosphoinositide binding site (9), which seems necessary for efficient
incorporation of AP-2 complexes into CCPs (10). Clathrin assembly at
the plasma membrane requires plasma membrane-bound AP-2 complexes (11,
12) and is thought to result from direct AP-2/clathrin interactions.
Dynamin directly binds to salt-stripped membranes and to phospholipids
containing liposomes (13-15), suggesting that dynamin might directly
interact with the plasma membrane in vivo. This hypothesis
was confirmed by the fact that dynamin is homogeneously redistributed
at the plasma membrane when CCP assembly is inhibited (8). Its
localization to CCPs requires its C-terminal proline-rich domain (16),
which binds to the SH3 domain of amphiphysin (17). Recently, several
new CCP-associated proteins were identified including Eps15 (18),
amphiphysin (19, 20), and epsin (21). The mechanisms by which these
accessory coat proteins are targeted to CCPs have not yet been investigated.
-adaptin ear
domain, the Eps15 binding site on AP-2 (26, 27), is involved in the
targeting of AP-2 to CCPs (6-8) have suggested that Eps15 may be part
of the AP-2 docking machinery. This hypothesis is strengthened by the
fact that an Eps15 mutant lacking EH domains inhibits CCP assembly (8).
Eps15 is a conserved protein (28, 29) organized in three structural
domains. The N-terminal domain (DI) contains three repeats of ~70
amino acids homologous to each other and to equivalent domains found in
proteins from humans, yeast, and nematodes. These domains were called
EH (30), for Eps15 Homology, and defined a
novel protein-protein interacting module (31) that recognizes NPF-based
motifs (32). The central domain (DII) contains heptad repeats required
for coiled-coil structures and is involved in the dimerization of Eps15
(33, 34). The C-terminal domain (DIII) contains the AP-2 binding region
(26), which spans ~120 amino acids (24) and contains three
independent AP-2 binding sites (27). Therefore, as Eps15 does not
contain any known plasma membrane targeting signals, its localization
to CCPs is likely to be mediated by protein-protein interactions
through its structural domains. The aim of this study was to identify
these signals. With this goal in mind, we generated mutant forms of
Eps15 and followed their intracellular localization. Their effect on
clathrin-dependent endocytosis was further analyzed and
compared with their capacity or inability to localize in CCP.
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
95/295 were described previously (8, 24, 26). The deleted mutants
were obtained by polymerase chain reactions and introduced within Eps15
subcloned between the BamHI/XhoI sites of the
PGEX5.1 vector using appropriate restriction sites. Briefly, deletion
of the central coiled-coil domain (ECC) was obtained by deleting a
635-base pair region corresponding to nucleotides 960-1605 of human
Eps15, and the mutated DNA fragment was introduced within the Eps15
sequence using the HindIII (825) and ClaI (1937) sites. Mutants of the C-terminal domain were obtained by introducing stop codons in the corresponding lower primers at position 1856 (EA/P/C), 2298 (EP/C), or 2544 (EC). The mutated polymerase chain reaction fragments were then introduced within the Eps15 sequence
using the BglII (1337) and XhoI sites. To
generate a Eps15 mutant lacking only AP-2 binding sites (EAP-2), a
354-base pair region (1856 to 2298) was deleted as described previously (24). All of the different constructs were excised from the PGEX5.1
vector using the BamHI/XhoI sites, purified on
agarose gel, and then subcloned into the
BglII/SalI sites of the EGFP-C2 vector
(CLONTECH). Restriction enzymes and T4 DNA ligase
were from Amersham Pharmacia Biotech. All of the constructs were
checked by nucleotide sequencing (Thermosequenase, Amersham Pharmacia Biotech). Sequences of the different primers used to generate the Eps15
mutants are available on request.
RESULTS
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
View larger version (95K):
[in a new window]
Fig. 1.
The structural domains of Eps15 are not
sufficient coated pit targeting signals. HeLa cells transiently
transfected with DI (a and b), DII (c
and d), or DIII (e and f) GFP
constructs were fixed, permeabilized, processed for fluorescence
microscopy using the AP.6 antibody directed against AP-2, and revealed
by a Texas Red-labeled secondary antibody as described under
"Experimental Procedures." The cells were then observed under an
epifluorescence microscope attached to a cooled CCD camera. The focus
was on AP-2 dots on the planar plasma membrane adherent to the
coverslip. a, c, and e, green
fluorescence emitted by GFP. b, d, and
f, red fluorescence emitted by Texas Red corresponding to
AP-2 complexes. Insets show higher magnifications of
representative areas of the plasma membrane; in c and
e, a region under the nucleus was selected because of its
lack of cytosolic GFP staining (see also Fig. 2, a and
g and Fig. 3a).
95/295 mutant (8) and
indicated that expression of the DIII construct also inhibits
clathrin-coated pit assembly. Nevertheless, the DIII construct did not
colocalize with the AP-2 dots still present at the plasma membrane
(Fig. 1, e, f, and insets), showing
that the AP-2 binding domain is not a sufficient coated pit targeting signal. The lack of plasma membrane punctate staining observed for each
structural domain was not due to an excess of cytosolic GFP, because
brief permeabilization of the transfected cells before fixation
effectively washed out cytosolic GFP constructs but did not reveal any
specific plasma membrane-associated staining (data not shown).
Altogether, these results show that none of the three structural
domains of Eps15 is sufficient for CCP targeting.
C; data not shown) or the
763-896 region (EP/C; Fig.
2c) showed a bright plasma
membrane punctate staining. Furthermore, the plasma membrane punctate
staining completely colocalized with AP-2 (Fig. 2, c,
d, and insets), showing that EP/C is targeted
to CCPs. Thus, the proline-rich region of Eps15, responsible for
binding to SH3 domain containing proteins, is not necessary for its
targeting to CCPs.
View larger version (76K):
[in a new window]
Fig. 2.
AP-2 binding sites are required for coated
pit targeting of Eps15. HeLa cells transiently transfected with
Eps15 (a and b), E P/C (c and
d), EA/P/C (e and f), or EAP-2
(g and h) GFP constructs were processed for
fluorescence microscopy as for Fig. 1. The same fields are shown in
a and b, c and d,
e and f, and g and h.
a, c, e, and g, green
fluorescence emitted by GFP. b, d, f,
and h, red fluorescence emitted by Texas Red corresponding
to AP-2 complexes. Insets show higher magnifications of
representative areas.
The role of AP-2 binding sites was investigated using two different
constructs; EA/P/C lacking the entire C-terminal region after amino
acid 620 and EAP-2 lacking only the AP-2 binding sites (621-738
region). As shown in Fig. 2, these two constructs showed a very faint
plasma membrane staining (Fig. 2, e and g). This
very faint staining still presented some colocalization with AP-2 (Fig.
2, e-h and insets), showing that the constructs
could be found in CCPs. However, the plasma membrane staining was
highly reduced compared with that observed for both wild type Eps15
(Fig. 2a) and for all of the constructs containing both EH
domains and AP-2 binding sites (Fig. 2c and Fig. 3,
a and c), showing that AP-2 binding sites play an
important role in CCP targeting of Eps15. Noticeably, in contrast to
endogenous Eps152 and
transfected GFP-Eps15 (Fig. 2a), some constructs (including EP/C (Fig. 2c) and EA/P/C (Fig. 2e)) were
found in the nucleus. Interestingly, the Eps15-related protein, Eps15r,
is found both in plasma membrane CCPs and in the nucleus (40). Thus,
Eps15 mutants may reveal a possible nucleocytoplasmic traffic for
Eps15.3
Finally, the role of the central dimerization domain in coated pit
localization was also tested. The ECC construct lacking the
coiled-coil domain colocalized with AP-2 at the plasma membrane (Fig.
3, a, b, and
insets), showing that the coiled-coil domain is not required
for CCP targeting of Eps15. However, we repeatedly noticed that the CCP
staining observed for ECC (Fig. 3a) was fainter than for
the full-length Eps15 (Fig. 2a). Compared with EP/C (Fig.
2c), which only lacks the C-terminal and proline-rich regions, weaker CCP staining was also observed for the ECC+P/C (Fig.
3c) lacking the coiled-coil domain, the C-terminal, and the
proline-rich regions. Altogether, these results suggest that the
coiled-coil domain does not provide specific targeting information but
rather helps to enhance the number of Eps15 molecules present in a
given CCP.
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We next checked the effect of all of the Eps15 mutants (described
above) on clathrin-dependent endocytosis. These mutants can
be classified in two groups. Group I includes DIII and E95/295 that
affect CCP assembly, and group II includes all of the other mutants
that do not affect CCP assembly (Fig. 6). Indeed, in the latter group,
clathrin-dependent endocytosis could be affected at a later
step, i.e. CCP invagination and/or coated vesicle formation. The effect of these mutants on Tf uptake was therefore tested. Expression of group II mutants did not inhibit internalization of
Cy3-conjugated Tf (Fig. 4B and
data not shown) whereas a strong inhibition was observed with group I
mutants (Fig. 4A and data not shown).
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We next verified that the lack of inhibition of Tf uptake by group II
mutants was not due to lower expression levels of group II mutants
compared with group I mutants. We took advantage of the fact that
inhibition of clathrin-dependent endocytosis induces an
increase in the number of Tf-R at the cell surface (41-44). Indeed, as
shown in Fig. 4A, cells expressing the E95/295 construct (a) presented both an inhibition of internalization of
Cy3-Tf (b) and an increase of cell surface Tf-R
(c) compared with neighboring untransfected cells. In
contrast, no increase of cell surface Tf-R was observed in cells
expressing group II mutants that did not inhibit Cy3-Tf uptake (Fig.
4B and data not shown). An increase of cell surface Tf-R was
then used to follow the inhibition of clathrin-dependent
endocytosis. HeLa cells transiently transfected with group I, group II,
and control constructs were analyzed by flow cytometry. Cells
expressing identical levels of GFP constructs were selected (Fig.
5a, region 2) and
analyzed for cell surface Tf-R expression. As shown in Fig.
5b, cells expressing the DII construct presented similar
levels of cell surface Tf-R compared with cells expressing the control
construct D32, which do not inhibit clathrin-dependent
endocytosis (24). Similar results were also found for cells expressing
the ECC construct (data not shown). Cells expressing either DI or
EA/P/C constructs did not show increased cell surface Tf-R (Fig.
5b). Rather they expressed a lower level of cell surface
Tf-R compared with that found for both DII and D32 constructs. Only
cells expressing either DIII (Fig. 5b) or E95/295 (data
not shown) showed a clear increase of cell surface Tf-R compared with
cells expressing the control D32 construct. Therefore, the
quantitative results obtained by flow cytometry confirm those obtained
by Tf uptake experiments and show that, at identical expression levels,
group I but not group II mutants inhibit CCP functions.
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DISCUSSION |
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TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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The present results extend our previous study and indicate that EH
domain-binding protein(s), together with the AP-2 complex, play an
important role in coated pit targeting of Eps15 (summarized in Fig.
6). Furthermore, they show that the
inhibitory effect of Eps15 mutants correlates with inhibition of CCP
assembly.
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Results obtained by several groups have shown that Eps15 EH domains bind to numerous proteins through NPF-based motifs (21, 32). Some of the identified proteins including RAB/RABr are not found in CCPs nor involved in clathrin-dependent endocytosis and therefore can be excluded as physiological partners for Eps15 targeting. The most interesting candidate is the recently identified EH domain-binding protein, epsin. Like Eps15, epsin is a constitutive component of CCPs that is associated with AP-2 and required for clathrin-dependent endocytosis. Interestingly, overexpressed wild type epsin is localized to the cytosolic face of the plasma membrane in regions devoid of clathrin coat (21). This is in agreement with a role of epsin as a plasma membrane-associated docking protein, which could therefore link Eps15 to the plasma membrane. Furthermore, Eps15 recruitment into CCPs also requires binding to AP-2. The fact that AP-2/Eps15 interaction sites (26) are involved in their respective targeting to CCPs (6-8) suggests that Eps15 is targeted to CCPs complexed to AP-2.
The Eps15 mutants can be classified as group I mutants, which inhibit
both CCP assembly and clathrin-dependent endocytosis and
group II mutants, which do not (Fig. 6). The group I mutants contain
the AP-2 binding sites. However, the presence of AP-2 binding sites is
not sufficient for these inhibitory effects because the ECC
construct that contains both EH domains and the AP-2 binding domain did
not inhibit coated pit assembly nor clathrin-dependent endocytosis. The ECC construct was still targeted to CCP (Fig. 3)
whereas DIII and E95/295 were not (see Fig. 1 and Ref. 8). Therefore, the inhibitory effects of Eps15 mutants on
clathrin-dependent endocytosis requires both the presence
of AP-2 binding sites and a lack of CCP localization.
Comparable domain requirements were also reported for dynamin. Dynamin mutants lacking the pleckstrin homology domain were recently shown to inhibit clathrin-dependent endocytosis of Tf (45-47). As previously shown for GTPase-deficient mutants (48), the C-terminal amphiphysin binding region is required for the inhibitory effect of the mutants on clathrin-dependent endocytosis (47). Furthermore, as observed for Eps15 with EH domains, the autonomously expressed dynamin pleckstrin homology domain does not inhibit clathrin-dependent endocytosis (49, 50).
Recently, the ear domain of -adaptin, the Eps15 binding site on
AP-2, was shown to bind to many other proteins including epsin,
amphiphysin, auscilin, and AP-180 (51). However, auxillin and AP-180
are only expressed in neuronal cells (52, 53); Eps15, epsin, and
amphiphysin seemed to be the main -ear domain partners in peripheral
cells. Interestingly, all of these different proteins bear DPF repeats
first found in the AP-2 binding domain of Eps15 (26) and were shown to
share with Eps15 the same -ear binding site (51). We could not
formally exclude the possibility that the effects that we observed by
expression of AP-2 binding sites containing Eps15 mutants on CCPs were
because of a general inaccessibility of the -ear domain.
Nevertheless, the increasing number of -ear binding proteins
suggests a very important role of this AP-2 domain in clathrin coat
function, an hypothesis confirmed by the fact that expression of
-ear inhibits clathrin-dependent internalization of Tf.
What could be these functions? The -ear domain could bring accessory
proteins to the pit as it is thought for dynamin via amphiphysin (39).
Another possibility, and both are not exclusive, is that -ear plays
an active role in the recruitment of AP-2 complexes onto the plasma
membrane. This hypothesis is sustained by the fact that the ear domains
of -, - and 
-adaptins are the most divergent parts of assembly
protein complexes (54-57) and could therefore discriminate between
distinct docking machinery on their target membranes. The fact that an
-ear domain GFP fusion protein is efficiently targeted to CCP (8)
shows that this domain effectively acts as a sufficient coated pit
targeting signal. In this model, epsin and Eps15 seemed to be
interesting potential candidates as constituents of the plasma
membrane-associated AP-2 docking machinery.
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ACKNOWLEDGEMENTS |
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We thank V. Collin and V. Mallarde for helpful technical assistance and D. Ojcius for careful reading of the manuscript.
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FOOTNOTES |
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* This work was supported by grants from the Association pour la Recherche contre le Cancer (ARC), from the Fondation Princesse Grace de Monaco, and from Human Frontier Science Program (grant number RG404/96).The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
¶ To whom correspondence should be addressed: INSERM E9925, Faculté Necker-Enfants Malades, 156 rue de Vaugirard, 75730 Paris, Cedex 15, France. Tel.: 33-1-40-61-56-38. Fax: 33-1-40-61-56-38. E-mail: benmerah@necker.fr.
Supported by Ligue Nationale contre le Cancer.
2 A. Benmerah, unpublished observation.
3 V. Poupon, N. Cerf-Bensussan, A. Dautry-Varsat, and A. Benmerah, manuscript in preparation.
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ABBREVIATIONS |
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The abbreviations used are: AP-2, plasma membrane clathrin-associated protein complex; AP-1, Golgi clathrin-associated protein complex; CCP(s), clathrin-coated pit; EH, Eps15 homology; GFP, green fluorescent protein; Tf, transferrin; Tf-R(s), transferrin receptor; PBS, phosphate-buffered saline; BSA, bovine serum albumin.
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REFERENCES |
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TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
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