| HOME | HELP | FEEDBACK | SUBSCRIPTIONS | ARCHIVE | SEARCH | TABLE OF CONTENTS |
|
|
|
|||||||
|
|||||||||
J. Biol. Chem., Vol. 277, Issue 21, 18477-18482, May 24, 2002
| ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
From the
Received for publication, February 25, 2002, and in revised form, March 7, 2002
The GGAs (Golgi-localizing,
In mammalian cells, newly synthesized lysosomal enzymes are
modified posttranslationally to acquire the mannose 6-phosphate recognition marker (1). These enzymes bind to the lumenal domains of
sorting receptors through their mannose 6-phosphate recognition markers
at the trans-Golgi network (TGN)1
and are targeted to acidified endosomes and lysosomes. The 46-kDa cation-dependent mannose 6-phosphate receptor (CD-MPR) and
the 275-kDa cation-independent mannose 6-phosphate receptor
(CI-MPR/insulin-like growth factor-II receptor) are type I
membrane-spanning glycoproteins known to mediate the processes of
recognition and sorting of these enzymes (2). Recently a family of
multidomain proteins named the Golgi-localized, Results from yeast two-hybrid experiments suggest a significant
difference in the affinity of binding between the CI-MPR and CD-MPR and
their GGA-binding partners. In these studies, the C-terminal tail of
the CI-MPR bound to the VHS domains of the GGAs with higher affinity
than did the corresponding region of the CD-MPR (10, 13). There also
was a difference in the relative affinity of the CD-MPR cytoplasmic
tail for the VHS domains of the different GGAs. Puertollano et
al. (10) showed that the CD-MPR bound well to the VHS domain of
GGA1, but only poorly to that of GGA3, and not at all to GGA2. In
contrast, they found that the cytoplasmic tail of the CI-MPR bound to
the VHS domains of all three GGAs with about equal affinity. Takatsu
et al. (13) on the other hand found that the cytoplasmic
tail of the CI-MPR but not the CD-MPR interacted with the VHS domain of GGA1.
In the present study we have examined the basis for the differences in
binding of the two MPRs to the GGAs. GST fusion peptides were generated
with various single and double amino acid substitutions of the CD-MPR
C-terminal region to more closely mimic the sequence of the CI-MPR
C-terminal peptide. The ability of these GST peptides to bind to
GGAs1-3 was measured in GST pull-down assays. These experiments have
identified several residues that significantly increase binding to the
VHS domains of the GGAs. Cell lines stably transfected with the CD-MPR
mutants that have improved GGA binding exhibit increased efficiency of
cathepsin D sorting. This is consistent with the idea that lysosomal
sorting at the TGN requires the direct participation of GGAs.
Antibodies--
The anti-Myc monoclonal antibody was purchased
from Santa Cruz Biotechnology (Santa Cruz, CA). The anti-HA monoclonal
was from Covance (Berkeley, CA). Anti-bovine CD-MPR polyclonal antibody and anti-human cathepsin D polyclonal antibody were generated in this laboratory.
Plasmid Construction--
The construct for the GST fusion
encoding the wild-type bovine CI-MPR 163-amino acid cytoplasmic tail
was made by PCR and ligation into the vector pGEX6P-1 (Amersham
Biosciences) as described (11). Residues 1-145 of the CI-MPR tail were
subsequently deleted out by designing primers and using the
QuickChangeTM system (Stratagene, La Jolla, CA) to generate
a GST CI-MPR peptide fusion incorporating only the C-terminal 18 amino
acids of the cytoplasmic tail. The GST CD-MPR peptide construct was
generated by annealing sense and antisense oligonucleotides
corresponding to the C-terminal 18 amino acids of the bovine CD-MPR
cDNA and ligating the double-stranded products into
EcoRI/XhoI-digested pGEX-5X-3 (Amersham
Biosciences). Mutagenesis of the CI- and CD-MPR cytoplasmic tails was
performed using primers incorporating the desired mutations with the
QuickChange system.
myc-GGA1pCR3.1 and GGA3pCR3.1 were generous gifts from Juan Bonifacino
(National Institutes of Health). GGA2-HApRK5 was kindly provided by
Veli-Pekka Lehto (University of Oulu). To construct myc-GGA1 and
GGA2-HA in the pFB1 vector (Invitrogen, Carlsbad, CA) for expression in
SF9 insect cells, myc-GGA1pCR3.1 and GGA2-HApRK5 were double-digested
with BamHI/NotI, and the cDNA inserts were ligated with BamHI/NotI-digested pFB1 to generate
myc-GGA1pFB1 and GGA2-HApFB1. myc-GGA3pFB1 was constructed in two steps
as follows. A SalI restriction site was engineered into
myc-GGA1pFB1 by substituting the codons for Leu-10 and Glu-11 of
the GGA1 cDNA by the QuickChange method. Similarly, a
SalI site was engineered into GGA3pCR3.1 by substituting the
codons for Glu-7 and Ser-8 of the GGA3 cDNA. myc-GGA3pFB1 was
subsequently constructed by substituting the
SalI/NotI fragment of myc-GGA1pFB1 encoding the GGA1 cDNA with the corresponding SalI/NotI
fragment encoding the GGA3 cDNA. The various truncation mutants
were generated using primers incorporating a stop codon at the desired
position with the QuickChange system.
Mutations in full-length CD-MPR were introduced into the cDNA
subcloned in the vector pBillNeo (15) by the QuickChange method using
oligonucleotide pairs incorporating the desired mutations. All
constructs and mutations were confirmed to be correct by
dideoxynucleotide sequencing.
Protein Expression--
The various GST CI- and CD-MPR fusion
proteins were expressed in the Escherichia coli strain
BL21(RIL) (Stratagene) essentially as described (16). Cells from 1 liter of culture were lysed into 20 ml of CellLytic B reagent (Sigma),
sonicated briefly, and centrifuged at 27,000 × g at
4 °C for 15 min to remove insoluble material. The clarified lysate
was then mixed by tumbling at 4 °C for 4 h with
glutathione-Sepharose 4B (Amersham Biosciences) pre-equilibrated with
20 mM Tris·Cl, pH 7.5, containing 0.1% Triton X-100.
Following 4 washes with the 20 mM Tris, 0.1% Triton X-100 buffer and a single wash with detergent-free 50 mM
Tris·Cl, pH 8.0, the GST fusion proteins were competitively eluted
with 10 mM reduced glutathione in 50 mM
Tris·Cl, pH 8.0. Proteins eluted with reduced glutathione were
dialyzed overnight against phosphate-buffered saline before use in
pull-down experiments.
myc-GGA1pFB1, GGA2-HApFB1, and myc-GGA3pFB1 were transformed into
E. coli DH10Bac competent cells to generate recombinant bacmids as per the manufacturer's protocol (Invitrogen). Bacmid DNAs
were transfected into SF9 insect cells to produce recombinant baculoviruses that were amplified and used to express the various GGAs
in the insect cells. Insect cells expressing the GGA proteins were
routinely harvested 48 h post-infection, lysed into cold buffer A
(25 mM Hepes-KOH, pH 7.2, 125 mM potassium
acetate, 2.5 mM magnesium acetate, 1 mM
dithiothreitol, and 0.4% Triton X-100) containing protease inhibitor
mixture (Roche Diagnostics, Indianapolis, IN) by sonication, and
centrifuged at 20,000 × g for 10 min. The supernatant
containing the GGA protein was stored at Binding Assays--
The binding of the various GST fusions with
the GGA proteins was assayed in buffer B (buffer A with 0.1% Triton
X-100) in a final volume of 300 µl in 1.5-ml pre-siliconized
microcentrifuge tubes (Midwest Scientific, Valley Park, MO). Routinely,
the GST fusion proteins were first immobilized at room temperature on 30 µl of packed glutathione-Sepharose to concentrations of 3-6 mg/ml. The beads with bound proteins were pelleted by centrifugation at
750 × g for 1 min and the beads washed once with cold
buffer B, and 300 µl of the SF9 cell lysate in buffer A at a final
concentration of 2-5 mg/ml was added to the washed beads. To determine
binding to AP-1, 300 µl of bovine adrenal cytosol (8 mg/ml) in buffer B was added to the washed beads. The binding reactions were allowed to
proceed for 3 h at 4 °C with tumbling, following which the samples were subjected to centrifugation at 750 × g
for 1 min. An aliquot of the supernatant was saved, and the pellets
were washed four times each by resuspension in 1 ml of cold buffer B by
centrifugation at 750 × g. The washed pellets were
resuspended in SDS sample buffer and heated at 100 °C for 5 min.
Unless indicated otherwise, 1% of each pellet and supernatant fraction
was loaded on SDS gels.
Electrophoresis and Immunoblotting--
Proteins were resolved
on 10% SDS-polyacrylamide gels and transferred to nitrocellulose.
Blots were blocked with TBST (10 mM Tris·Cl, pH 7.5, 150 mM NaCl, 0.1% Tween 20) containing 5% non-fat milk for
1 h at room temperature. The blots were then probed with primary
antibodies as indicated in the individual figure legends, followed by
horseradish peroxidase-conjugated anti-mouse IgG. The
immunoreactive bands were visualized on x-ray films using
enhanced chemiluminescence (Amersham Biosciences).
Stable Cell Transfectants--
Stable cell lines expressing the
various CD-MPR mutants were generated by transfection of the pBillNeo
constructs into CI-MPR negative mouse L cells (D-9) and the subsequent
selection of clones propagated in G418-containing media. Transgene
protein expression was determined by Western blotting. The CD-MPR
protein levels of the various cell lines were compared with the
non-transfected D-9 cells by loading equal quantities of total protein
from cell lysates on SDS gels, transferring to nitrocellulose, and
quantifying the immunoreactive bands by ECL using the Kodak Digital
Imaging System (Eastman Kodak Co.).
Pulse-Chase and Cathepsin D Sorting Assays--
Metabolic
labeling and sorting of cathepsin D by the various CD-MPR mutant cell
lines were performed essentially as described (17). Briefly, mouse L
cells were plated onto 6-well plates 2 days prior to labeling. Cell
monolayers at ~90% confluency were washed twice with
cysteine/methionine-free Effect of Mutations in the CD-MPR Tail on GGA
Binding--
Although both the CD-MPR and the CI-MPR contain acidic
cluster-dileucine sequences near the C terminus of their cytoplasmic tails, inspection of the amino acid sequences of the bovine species shows several differences in this region as well as in the flanking residues (Fig. 1). Setting the first leucine
of the dileucine motif to 0, there are differences at positions The C-terminal Met Residue Inhibits GGA Binding--
The finding
that the Pro Addition of Alanines to the C Termini of the MPRs Inhibits GGA
Binding--
The acidic cluster/dileucine motifs of both MPRs are
located two residues from the C terminus of the cytoplasmic tails (Fig. 1). In sortilin, another membrane receptor known to interact with the
GGAs, the acidic cluster cluster/dileucine motif is one residue from
the carboxyl end (12). This prompted us to ask whether the positioning
of the acidic cluster-dileucine motif relative to the C terminus of the
protein influences binding to the GGAs. To explore this issue we
constructed GST CI-MPR and CD-MPR peptides with four alanine residues
extending beyond the usual C-terminal residue. The CD-MPR peptide also
contained the Pro MPR Binding to the GGAs Correlates with Cathepsin D Sorting in
Cells--
In a previous study (17) published before the discovery of
the GGAs, we reported that CI-MPR-negative mouse L cells expressing CD-MPR with the Pro
Another potential explanation for the improved ability of the mutant
receptors to sort cathepsin D is that the amino acid substitutions
enhance binding to the AP-1 adaptor protein complex that is also
implicated in packaging the MPRs into transport vesicles in the TGN
(19). The various GST fusion peptides were therefore tested for their
ability to bind AP-1 in pull-down assays. As shown in Fig.
5, the full-length CD-MPR cytoplasmic tail
bound only a trace amount of AP-1 in this assay compared with strong binding by the CI-MPR full-length cytoplasmic tail. None of the GST
peptides having wild-type or mutant acidic cluster-dileucine sequences
bound detectable levels of AP-1. This indicates that the AP-1 binding
to the full-length CI-MPR cytoplasmic tail observed in this assay is
not mediated by the acidic cluster-dileucine motif, in agreement with
our previous study (11). Furthermore, it suggests that the improved
efficiency of cathepsin D sorting exhibited by three of the CD-MPR
mutants is not a consequence of enhanced binding to AP-1.
The results presented in this study provide a number of new
insights concerning the interaction of the GGAs with acidic
cluster-dileucine motifs. First, our data show that the weak binding of
the CD-MPR to the GGAs relative to that observed with the CI-MPR is due
to two amino acid differences in the acidic clusters of these receptors along with a difference in the C-terminal residue located two residues
downstream of the dileucines. Within the acidic clusters, we found
that an Asp residue at the The other key observation is that a Met at the C-terminal position, as
occurs in the CD-MPR, inhibits GGA binding, whereas a Val at that
position, as found in the bovine CI-MPR, allows strong binding. This
finding is significant because it indicates that the GGAs recognize the
C-terminal residue as well as the acidic cluster-dileucine motif.
Furthermore, because the addition of four alanines to the C-terminal
residue strongly inhibited GGA binding, it appears that the location of
the acidic cluster-dileucine motif two residues upstream from the C
terminus is critical for optimal binding to the GGAs. The effects of
these residues on binding was found with all three GGAs, demonstrating
that the different GGAs recognize common elements in the acidic
cluster-dileucine motifs.
While this manuscript was in preparation, two groups (20, 21) reported
the crystal structure of the VHS domains of human GGA1 and GGA3
complexed with the acidic cluster-dileucine motifs of the MPRs. The VHS
domain is a right-handed superhelix of eight helices. Helices 6 and 8 form a surface that makes extensive contacts with amino acid residues
The second important finding in our study is the strong correlation
between the apparent binding affinities of the various acidic
cluster-dileucine motifs to GGAs1-3 in the in vitro
pull-down assays and the efficiency of cathepsin D sorting in mouse L
cells expressing CD-MPRs with the different mutations. These data
provide evidence that GGAs play a key role in packaging CD-MPRs with
bound acid hydrolases into transport vesicles that are delivered to the
endosome/lysosome system. A similar correlation emerged from studies of
CI-MPRs that have a variety of mutations in their acidic cluster-dileucine motifs (11, 18, 22-24). None of the mutations in the
CD-MPR acidic cluster-dileucine motif that enhanced GGA binding
resulted in AP-1 binding as measured by the pull-down assays. In fact,
the full-length CD-MPR cytoplasmic tail bound AP-1 very poorly in this
assay in contrast to the findings with the CI-MPR cytoplasmic tail.
This probably reflects the insensitivity of the assay because Honing
and co-workers (25) have reported that the cytoplasmic tail of the
CD-MPR binds AP-1 with high affinity. These investigators used surface
plasmon resonance to identify two independent sequences (amino acids
34-43 and 49-67) that bind AP-1 with Kd values of
14 nM. Whereas the 49-67 sequence includes the acidic
cluster-dileucine motif, they showed that mutation of the dileucines to
alanines had no effect on AP-1 binding. This is significant because
mutation of the dileucines abolishes GGA binding, and cells expressing
CD-MPRs with this mutation exhibit extremely poor cathepsin D sorting
(17, 26). Thus although AP-1 may have a role in packaging the CD-MPR
into clathrin-coated vesicles at the TGN, either it handles only a
small fraction of the cargo relative to the GGAs or it relies on the
GGAs to present the MPRs for incorporation into AP-1 transport
vesicles. Our data do not distinguish between these possibilities.
Finally, it is curious that the CD-MPR, in contrast to the CI-MPR,
would evolve with an acidic cluster-dileucine motif that fails to
provide optimal interaction with the GGAs. The CD-MPR does function to
sort acid hydrolases in cells, so perhaps it works sufficiently well so
that pressure has not been exerted to evolve into a more efficient
receptor. Alternatively, the CD-MPR may be subject to some type of
regulation that modulates GGA interaction. The cytoplasmic tail of the
CD-MPR contains a casein kinase II phosphorylation site just upstream
of the acidic cluster-dileucine motif (the Ser is at position We thank Rosalind Kornfeld for reading of the
manuscript and helpful comments.
*
This work was supported in part by National Institutes of
Health Grant CA08759 (to S. K.).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.
§
Both authors contributed equally to this work.
¶
Recipient of a post-doctoral fellowship from the Singapore
National Science and Technology Board.
**
To whom correspondence should be addressed: Washington University
School of Medicine, Division of Hematology, 660 S. Euclid Ave., Campus
Box 8125, St. Louis, MO 63110. Tel.: 314-362-8803; Fax: 314-362-8826;
E-mail: skornfel@im.wustl.edu.
Published, JBC Papers in Press, March 8, 2002, DOI 10.1074/jbc.M201879200
The abbreviations used are:
TGN, trans-Golgi
network;
CD-MPR, cation-dependent mannose 6-phosphate
receptor;
CI-MPR, cation-independent mannose 6-phosphate receptor;
GST, glutathione S-transferase;
HA, hemagglutinin.
Interaction of the Cation-dependent Mannose
6-Phosphate Receptor with GGA Proteins*
§¶,
,, and**
Department of Internal Medicine, Washington
University School of Medicine, St. Louis, Missouri 63110 and the
Department of Chemistry, Southwestern University,
Georgetown, Texas 78627
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-adaptin ear homology domain, ARF-binding)
are a multidomain family of proteins implicated in protein trafficking
between the Golgi and endosomes. Recent evidence has established that
the cation-independent (CI) and cation-dependent (CD)
mannose 6-phosphate receptors (MPRs) bind specifically to the VHS
domains of the GGAs through acidic cluster-dileucine motifs at the
carboxyl ends of their cytoplasmic tails. However, the CD-MPR binds the
VHS domains more weakly than the CI-MPR. Alignment of the C-terminal
residues of the two receptors revealed a number of non-conservative
differences in the acidic cluster-dileucine motifs and the flanking
residues. Mutation of these residues in the CD-MPR cytoplasmic tail to
the corresponding residues in the CI-MPR conferred either full binding
(H63D mutant), intermediate binding (R60S), or unchanged binding
(E56F/S57H) to the GGAs as determined by in vitro
glutathione S-transferase pull-down assays. Furthermore,
the C-terminal methionine of the CD-MPR, but not the C-terminal valine
of the CI-MPR, inhibited GGA binding. Addition of four alanines to the
C-terminal valine of the CI-MPR also severely reduced GGA binding,
demonstrating the importance of the spacing of the acidic
cluster-dileucine motif relative to the C terminus for optimal GGA
interaction. Mouse L cells stably expressing CD-MPRs with mutations
that enhance GGA binding sorted cathepsin D more efficiently than
wild-type CD-MPR. These studies provide an explanation for the observed
differences in the relative affinities of the two MPRs for the GGA
proteins. Furthermore, they indicate that the GGAs participate in
lysosomal enzyme sorting mediated by the CD-MPR.
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-ear-containing,
ARF-binding proteins (or GGAs) was discovered in mammals and in yeast
(3-7). These proteins have been shown to facilitate protein
trafficking from the TGN to lysosomes in mammalian cells and to the
vacuole in yeast (4, 5, 8, 9). The GGAs were found to bind to both the
CI-MPR and CD-MPR in yeast two-hybrid systems and in GST pull-down
assays (10-13). The binding was demonstrated to be a specific
interaction between acidic cluster-dileucine signals found near the C
termini of the MPRs and the N-terminal VHS domains of the GGAs. The
GGAs also bind to the ADP-ribosylation factor-GTP complex (ARF-GTP) that is localized to the TGN (6, 9, 14) and to clathrin (11, 14). These
observations are consistent with a model for lysosomal enzyme
trafficking involving the recruitment of the MPRs and their cargo by
the GGAs to the site of transport vesicle formation.
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
80 °C for use in the
binding assays.
-minimum Eagle's medium and labeled for
1 h with 1 ml of 1 mCi/ml Tran35S-label (ICN
Radiochemicals, Irvine, CA) in the presence of 20 mM Hepes
and 5 mM mannose 6-phosphate. Excess unlabeled methionine (10 mM final concentration) was added to initiate a 4-h
chase. Cells were then placed on ice and processed as described (18). The amount of cathepsin D sorted was determined by immunoprecipitating equivalent aliquots of the lysed cell and media high speed supernatants overnight at 4 °C with rabbit anti-human cathepsin D antiserum and
protein A-Sepharose beads (Repligen, Cambridge, MA). After four washes,
immunoprecipitates were subjected to 10% SDS-PAGE under non-reducing
conditions. Gels were treated with EN3HANCE (PerkinElmer
Life Sciences), dried, and exposed to Kodak X-Omat AR film at
70 °C. The resultant autoradiogram was used as a template to
excise from the gel the regions corresponding to the processed and
secreted forms of cathepsin D. The gel slices were then processed, and
the associated radioactivity was determined as described (17). The
percentage of cathepsin D sorted was calculated as the ratio of
radioactivity in the processed form to the sum of the processed and
secreted forms.
RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
1,
4, 7, and 8 and at +2 and +3. To evaluate the importance of these
differences in binding to the various GGAs, GST fusion peptides
incorporating the C-terminal 18 amino acids of the receptors were
generated with single or double substitutions of the CI-MPR residues
into the equivalent position of the CD-MPR peptide backbone. The
ability of these various mutant GST peptides to bind GGAs in pull-down assays was then compared with binding by the wild-type CI-MPR and
CD-MPR peptides. In preliminary experiments, we found that the GST
peptides with the wild-type MPR sequences bound GGAs to the same extent
as the GST full-length cytoplasmic tails. Fig. 2A shows that GGA2 binds much
better to the wild-type CI-MPR peptide than to the wild-type CD-MPR
peptide, confirming the previous report (10). Thus, analysis of 1% of
the GST CI-MPR peptide pellet gave a signal equivalent to that seen
with 25% of the GST CD-MPR pellet. Mutation of the His residue at
position 1 of the CD-MPR sequence to Asp resulted in a striking
increase in GGA2 binding, equivalent to that seen with the CI-MPR
peptide. Mutation of the Arg residue to a Ser at position 4 of the
CD-MPR sequence greatly enhanced GGA2 binding as well, although not
quite to the same extent as the His to Asp substitution. When the Glu
and Ser flanking residues at positions 8 and 7 were changed to Phe
and His, respectively, there was no significant alteration in GGA2 binding, indicating that these residues do not have a role in the
interaction with GGA2. In contrast, the residues downstream of the
dileucines strongly affect GGA2 binding. Thus substitution of the Pro
and Met residues at positions +2 and 3 with alanines resulted in GGA2
binding equal to that observed with the CI-MPR peptide. This result is
similar to that reported by Puertollano et al. (10) with
GGA3 using the yeast two-hybrid assay. The same results were obtained
when the binding of GGA1 and GGA3 to the various peptides was tested
(Fig. 2, B-D). In both cases the CI-MPR peptide bound the
GGAs much better than the CD-MPR peptide, and the His 
Asp, Arg Ser, and Pro Ala/Met Ala substitutions enhanced binding,
whereas the Glu Phe/Ser His mutation had no detectable effect
on binding.
View larger version (8K):
[in a new window]
Fig. 1.
Sequence of the C terminus of the CI-MPR and
CD-MPR cytoplasmic tails. Alignment of the C-terminal amino acids
of the bovine CI-MPR and the CD-MPR reveals a number of
non-conservative differences. Substituted residues are indicated with
arrows.
View larger version (30K):
[in a new window]
Fig. 2.
Effect of mutations in the CD-MPR tail on GGA
binding. A-D, specific mutations of the C-terminal
amino acid residues of the CD-MPR cytoplasmic tail to the corresponding
residues in the CI-MPR tail greatly enhance binding to all three GGA
VHS domains in GST pull-down experiments. 1% of the pellet
(P) and supernatant (S) were resolved on 10% SDS
gels, transferred to nitrocellulose, and probed with either the
anti-Myc or anti-HA antibody as described under "Experimental
Procedures." *, highlights the fact that the GST CD-MPR peptide does
bind to the VHS domain albeit very weakly relative to the GST CI-MPR
peptide, 25% of pellet and 5% of supernatant were loaded in this
case.
Ala/Met Ala substitution enhanced GGA binding
indicated that one or both of these residues was inhibitory. To pursue
this point, GST peptides were prepared in which the Pro and Met
residues were individually mutated to alanines. When these were tested
for binding to the GGA1 VHS domain, the peptide with the Met Ala
mutation exhibited a striking increase in GGA1 binding, whereas the
peptide with the Pro Ala substitution behaved similar to the
wild-type CD-MPR peptide (Fig. 2D). This demonstrates that
the C-terminal Met completely accounts for the inhibitory effect.
Because the C-terminal residue in the bovine CI-MPR is a valine, we
asked whether substitution of this bulky hydrophobic residue with a
methionine would influence GGA binding. As shown in Fig.
3, a GST CI-MPR peptide with the Val to Met
substitution bound GGA1 and GGA2 poorly when compared with the
wild-type peptide, supporting the interpretation that a Met at the +3
position inhibits binding to the GGAs.
View larger version (13K):
[in a new window]
Fig. 3.
C-terminal methionine of CD-MPR is inhibitory
to GGA binding. Substitution of the C-terminal valine of the
CI-MPR to methionine greatly impairs binding of the GST CI-MPR peptide
to the VHS domain of GGA1 and to a somewhat lesser extent to GGA2.
Proteins resolved on SDS gels were tranferred to nitrocellulose, and
immunoblotting was performed as described under "Experimental
Procedures."
Ala/Met Ala substitution so that GGA binding
could be more easily detected. As shown in Fig.
4, the addition of the four alanines
strikingly inhibited binding to all three GGAs. These findings indicate
that the position of the acidic cluster-dileucine motif relative to the
C terminus of the cytoplasmic tail has a major effect on GGA binding.
View larger version (31K):
[in a new window]
Fig. 4.
Binding of MPRs to the VHS domains requires a
precise spacing between the dileucines and the free C terminus. An
immunoblot of the binding reaction shows that extension of the terminal
carboxyl moiety by an additional four alanines from the native C
terminus drastically reduces binding of both the GST-CI MPR
pep (peptide) and the GST CD-MPR PM AA pep
(peptide) to all three GGA VHS domains.
Ala/Met Ala mutation sorted the acid
hydrolase cathepsin D more efficiently than cells expressing greater
amounts of wild-type CD-MPR. The current findings suggest that the
improved sorting efficiency may have been the result of enhanced
binding to the GGAs. To determine whether this correlation holds for
the other mutations that increase GGA binding, CI-MPR-negative L cells (clone D-9) were stably transfected with plasmids encoding bovine CD-MPRs with either Arg Ser, His Asp, or Glu Phe/Ser His substitutions. The ability of these cells to sort cathepsin D in
pulse/chase experiments was measured and compared with cells expressing
wild-type CD-MPR or CD-MPR with the Pro Ala/Met Ala mutation.
The results are summarized in Table I.
The non-transfected D-9 cells sorted 44 ± 3% of the cathepsin D
due to the endogenous CD-MPR. The sorting efficiency increased to
69 ± 4% in cells expressing 12-fold more wild-type CD-MPR but
was essentially unchanged in a cell line expressing only 4-fold more
wild-type CD-MPR. Cells expressing CD-MPR with the Glu Phe/Ser His mutation sorted 53 ± 2% of cathepsin D, which is not
significantly different from the non-transfected D-9 cells. This
mutation does not enhance GGA binding. In contrast, cells expressing
CD-MPR with either the Arg Ser or the His Asp mutations
exhibited a significant increase in cathepsin D sorting (57 ± 2 and 70 ± 4%, respectively) even though the receptor expression
level was only two times the basal level. Both of these mutations
increase GGA binding with the His Asp substitution having a greater
effect than the Arg Ser substitution. The cells expressing receptor
with the Pro Ala/Met Ala mutation sorted cathepsin D very
efficiently (84 ± 1%), confirming our previous findings. The
expression level of this mutant receptor was 4.5-fold the basal level,
which may explain why it is more effective than the His Asp and Arg
Ser mutants. Taken as a whole, these data reveal a strong
correlation between GGA binding and the efficiency of cathepsin D
sorting in cells.
Sorting of cathepsin D by L cells expressing mutant CD-MPRs
View larger version (29K):
[in a new window]
Fig. 5.
CD-MPR mutants with enhanced GGA interaction
do not show improved AP-1 binding. To determine whether the
increased sorting efficiency exhibited by the CD-MPR mutants was due to
improved binding to AP-1, GST CI/CD-MPR tail FL (full-length
cytoplasmic tail) and GST CI/CD-MPR pep (peptide) wild-type
and mutants were tested for their ability to bind AP-1 in in
vitro pull-down assays. 10% of pellet (P) and 3% of
supernatant (S) were loaded on the SDS gel. As seen from the
immunoblot, neither the wild-type GST CD-MPR peptide nor the mutants
that showed markedly enhanced GGA interaction display any binding to
AP-1.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
1 position greatly enhanced GGA binding
compared with a His at this position. This is consistent with our
previous study (11) showing that multiple residues in the acidic
cluster of the CI-MPR influence binding to GGA2. A Ser at position 4
also improved GGA binding relative to an Arg at that position. In both
instances the favorable residue is present in the acidic cluster of the
CI-MPR, whereas the unfavorable residue is found in the CD-MPR acidic cluster.
5 to +3 of the CI-MPR cytoplasmic tail and residues 4 to +3 of the
CD-MPR cytoplasmic tail. Among these residues, the dileucines and the
aspartate at position 3 have the most extensive interactions with the
VHS-binding site, whereas the other residues appear to contribute to a
lesser extent to the binding. These authors also implicated the
C-terminal flanking residues of the acidic cluster-dileucine motifs in
the binding to the VHS domain. They noted that the C-terminal
side-chain protrudes into a hydrophobic pocket. Furthermore, Misra
et al. (20) found that MPR sequences with two residues
distal to the dileucines gave optimal binding, whereas those with one
or three bound more weakly, and those with zero or four did not bind.
Peptides containing amidated C-terminal residues also bound very
weakly. Thus binding to the VHS domains requires a precise spacing
between the dileucines and the free C terminus. Finally, Misra et
al. (20) reported that the CI-MPR peptide bound 4-6-fold better
to the VHS domains of GGA1 and GGA3 than the CD-MPR peptide as
determined by isothermal titration calorimetry. These findings are in
good agreement with our results. Our data extend the work of Misra
et al. (20) and Shiba et al. (21) by identifying
the residues that account for the differences in CI-MPR and CD-MPR
binding to the VHS domains.
7, see
Fig. 1). The importance of phosphorylation of Ser-57 is not clear at
this time. Mauxion et al. (19) have suggested that
phosphorylation of this serine facilitates AP-1 recruitment to the TGN.
On the other hand, substitution of Ser-57 with an alanine or aspartate
did not influence acid hydrolase sorting in mouse cells (17, 27). It
may turn out that phosphorylation of Ser-57 regulates binding to the
GGAs under some circumstances.
ACKNOWLEDGEMENT
FOOTNOTES
ABBREVIATIONS
REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
1.
Kornfeld, S.,
and Mellman, I.
(1989)
Annu. Rev. Cell Biol.
5,
483-525[CrossRef][Medline]
[Order article via Infotrieve]
2.
Kornfeld, S.
(1992)
Annu. Rev. Biochem.
61,
307-330[CrossRef][Medline]
[Order article via Infotrieve]
3.
Poussu, A.,
Lohi, O.,
and Lehto, V. P.
(2000)
J. Biol. Chem.
275,
7176-7183 4.
Dell'Angelica, E. C.,
Puertollano, R.,
Mullins, C.,
Aguilar, R. C.,
Vargas, J. D.,
Hartnell, L. M.,
and Bonifacino, J. S.
(2000)
J. Cell Biol.
149,
81-94 5.
Hirst, J.,
Lui, W. W.,
Bright, N. A.,
Totty, N.,
Seaman, M. N.,
and Robinson, M. S.
(2000)
J. Cell Biol.
149,
67-80 6.
Boman, A. L.,
Zhang, C. J.,
Zhu, X.,
and Kahn, R. A.
(2000)
Mol. Biol. Cell
11,
1241-1255 7.
Takatsu, H.,
Yoshino, K.,
and Nakayama, K.
(2000)
Biochem. Biophys. Res. Commun.
271,
719-725[CrossRef][Medline]
[Order article via Infotrieve]
8.
Black, M. W.,
and Pelham, H. R.
(2000)
J. Cell Biol.
151,
587-600 9.
Zhdankina, O.,
Strand, N. L.,
Redmond, J. M.,
and Boman, A. L.
(2001)
Yeast
18,
1-18[CrossRef][Medline]
[Order article via Infotrieve]
10.
Puertollano, R.,
Aguilar, R. C.,
Gorshkova, I.,
Crouch, R. J.,
and Bonifacino, J. S.
(2001)
Science
292,
1712-1716 11.
Zhu, Y.,
Doray, B.,
Poussu, A.,
Lehto, V. P.,
and Kornfeld, S.
(2001)
Science
292,
1716-1718 12.
Nielsen, M. S.,
Madsen, P.,
Christensen, E. I.,
Nykjaer, A.,
Gliemann, J.,
Kasper, D.,
Pohlmann, R.,
and Petersen, C. M.
(2001)
EMBO J.
20,
2180-2190[CrossRef][Medline]
[Order article via Infotrieve]
13.
Takatsu, H.,
Katoh, Y.,
Shiba, Y.,
and Nakayama, K.
(2001)
J. Biol. Chem.
276,
28541-28545 14.
Puertollano, R.,
Randazzo, P. A.,
Presley, J. F.,
Hartnell, L. M.,
and Bonifacino, J. S.
(2001)
Cell
105,
93-102[CrossRef][Medline]
[Order article via Infotrieve]
15.
Johnson, K. F.,
Chan, W.,
and Kornfeld, S.
(1990)
Proc. Natl. Acad. Sci. U. S. A.
87,
10010-10014 16.
Drake, M. T.,
Downs, M. A.,
and Traub, L. M.
(2000)
J. Biol. Chem.
275,
6479-6489 17.
Johnson, K. F.,
and Kornfeld, S.
(1992)
J. Biol. Chem.
267,
17110-17115 18.
Lobel, P.,
Fujimoto, K., Ye, R. D.,
Griffiths, G.,
and Kornfeld, S.
(1989)
Cell
57,
787-796[CrossRef][Medline]
[Order article via Infotrieve]
19.
Mauxion, F.,
Leborgne, R.,
Munierlehmann, H.,
and Hoflack, B.
(1996)
J. Biol. Chem.
271,
2171-2178 20.
Misra, S.,
Puertollano, R.,
Kato, Y.,
Bonifacino, J. S.,
and Hurley, J. H.
(2002)
Nature
415,
933-937[CrossRef][Medline]
[Order article via Infotrieve]
21.
Shiba, T.,
Takatsu, H.,
Nogi, T.,
Matsugaki, N.,
Kawasaki, M.,
Igarashi, N.,
Suzuki, M.,
Kato, R.,
Earnest, T.,
Nakayama, K.,
and Wakatsuki, S.
(2002)
Nature
415,
937-941[CrossRef][Medline]
[Order article via Infotrieve]
22.
Johnson, K. F.,
and Kornfeld, S.
(1992)
J. Cell Biol.
119,
249-257 23.
Chen, H. J.,
Remmler, J.,
Delaney, J. C.,
Messner, D. J.,
and Lobel, P.
(1993)
J. Biol. Chem.
268,
22338-22346 24.
Chen, H. J.,
Yuan, J.,
and Lobel, P.
(1997)
J. Biol. Chem.
272,
7003-7012 25.
Honing, S.,
Sosa, M.,
Hille-Rehfeld, A.,
and von Figura, K.
(1997)
J. Biol. Chem.
272,
19884-19890 26.
Denzer, K.,
Weber, B.,
Hille-Rehfeld, A.,
von Figura, K.,
and Pohlmann, R.
(1997)
Biochem. J.
326,
497-505[Medline]
[Order article via Infotrieve]
27.
Breuer, P.,
Korner, C.,
Boker, C.,
Herzog, A.,
Pohlmann, R.,
and Braulke, T.
(1997)
Mol. Biol. Cell
8,
567-576[Abstract]
Copyright © 2002 by The American Society for Biochemistry and Molecular Biology, Inc.
CiteULike 
Complore 
Connotea 
Del.icio.us 
Digg 
Reddit 
Technorati What's this?
This article has been cited by other articles:
|
|
 |
|
  M. Larance, G. Ramm, and D. E. James The GLUT4 Code Mol. Endocrinol., February 1, 2008; 22(2): 226 - 233. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 V. Schmidt, A. Sporbert, M. Rohe, T. Reimer, A. Rehm, O. M. Andersen, and T. E. Willnow SorLA/LR11 Regulates Processing of Amyloid Precursor Protein via Interaction with Adaptors GGA and PACS-1 J. Biol. Chem., November 9, 2007; 282(45): 32956 - 32964. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 S. Kametaka, K. Moriyama, P. V. Burgos, E. Eisenberg, L. E. Greene, R. Mattera, and J. S. Bonifacino Canonical Interaction of Cyclin G associated Kinase with Adaptor Protein 1 Regulates Lysosomal Enzyme Sorting Mol. Biol. Cell, August 1, 2007; 18(8): 2991 - 3001. [Abstract] [Full Text] [PDF]
|
|
|
|
|
|
M. Duwel and E. J. Ungewickell Clathrin-dependent Association of CVAK104 with Endosomes and the Trans-Golgi Network Mol. Biol. Cell, October 1, 2006; 17(10): 4513 - 4525. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 D.-w. Lee, X. Zhao, F. Zhang, E. Eisenberg, and L. E. Greene Depletion of GAK/auxilin 2 inhibits receptor-mediated endocytosis and recruitment of both clathrin and clathrin adaptors J. Cell Sci., September 15, 2005; 118(18): 4311 - 4321. [Abstract] [Full Text] [PDF]
|
|
|
|
|
|
H. Bai, B. Doray, and S. Kornfeld GGA1 Interacts with the Adaptor Protein AP-1 through a WNSF Sequence in Its Hinge Region J. Biol. Chem., April 23, 2004; 279(17): 17411 - 17417. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 P. Ghosh, J. Griffith, H. J. Geuze, and S. Kornfeld Mammalian GGAs act together to sort mannose 6-phosphate receptors J. Cell Biol., November 24, 2003; 163(4): 755 - 766. [Abstract] [Full Text] [PDF]
|
|
|
|
|
|
P. Ghosh and S. Kornfeld Phosphorylation-induced Conformational Changes Regulate GGAs 1 and 3 Function at the Trans-Golgi Network J. Biol. Chem., April 11, 2003; 278(16): 14543 - 14549. [Abstract] [Full Text] [PDF]
|
|
|
|
|
|
R. Puertollano, N. N. van der Wel, L. E. Greene, E. Eisenberg, P. J. Peters, and J. S. Bonifacino Morphology and Dynamics of Clathrin/GGA1-coated Carriers Budding from the Trans-Golgi Network Mol. Biol. Cell, April 1, 2003; 14(4): 1545 - 1557. [Abstract] [Full Text] [PDF]
|
|
|
|
|
|
I. G. Mills, G. J.K. Praefcke, Y. Vallis, B. J. Peter, L. E. Olesen, J. L. Gallop, P. J. G. Butler, P. R. Evans, and H. T. McMahon EpsinR: an AP1/clathrin interacting protein involved in vesicle trafficking J. Cell Biol., January 21, 2003; 160(2): 213 - 222. [Abstract] [Full Text] [PDF]
|
|
|
|
 |
|
 B. Doray, K. Bruns, P. Ghosh, and S. A. Kornfeld Autoinhibition of the ligand-binding site of GGA1/3 VHS domains by an internal acidic cluster-dileucine motif PNAS, June 11, 2002; 99(12): 8072 - 8077. [Abstract] [Full Text] [PDF]
|
|
| |||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
