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From the
Received for publication, July 2, 2001
Rab11, a low molecular weight GTP-binding
protein, has been shown to play a key role in a variety of cellular
processes, including endosomal recycling, phagocytosis, and transport
of secretory proteins from the trans-Golgi network.
In this study we have described a novel Rab11 effector,
EF-hands-containing
Rab11-interacting protein (Eferin). In
addition, we have identified a 20-amino acid domain that is present at
the C terminus of Eferin and other Rab11/25-interacting proteins, such
as Rip11 and nRip11. Using biochemical techniques we have demonstrated
that this domain is necessary and sufficient for Rab11 binding in
vitro and that it is required for localization of Rab11 effector
proteins in vivo. The data suggest that various Rab
effectors compete with each other for binding to Rab11/25 possibly
accounting for the diversity of Rab11 functions.
Members of the Rab/Ypt GTPase family have emerged as important
regulators of vesicular trafficking (1). Rab proteins have been
proposed to mediate a variety of functions, including vesicle translocation and docking at specific fusion sites. Like all small GTPases, Rabs cycle between active (GTP-bound) and inactive (GDP-bound) conformations (2). In the GTP-bound state, Rab proteins can bind a
variety of downstream effector proteins, while GTP hydrolysis leads to
a conformational change in the switch region that renders the Rab
GTPase unrecognizable to its effector proteins (3, 4). A key question
in understanding the interactions between Rabs and their effectors
concerns the mechanisms by which Rab GTPases specifically bind a
diverse spectrum of effectors and how this is regulated by the common
structural motif used as a GTP switch. Biochemical and genetic studies
have identified several hypervariable regions that might be involved in
determining Rab specificity, including N and C termini, as well as the
Rab11a, 11b, and 25 are closely related members of Rab GTPase family
that have been implicated in regulating a variety of different
post-Golgi trafficking pathways, such as protein recycling (8),
phagocytosis (9), insulin-stimulated Glut4 insertion in the plasma
membrane (10), and membrane trafficking from early endosomes to the
trans-Golgi network (11). During the last few years
several Rab11/25-interacting proteins have been identified, including
Rab11BP/rabphilin-11, Rip11, nRip11, and myosin Vb (12-15). However,
the mechanisms of their function, as well as molecular aspects of their
interactions with Rab11, remain to be fully understood. In the present
study, we report the identification of EF-hands-containing Rab11/25-interacting protein (Eferin).
Furthermore, we characterized a Rab binding domain (RBD11) that is
present at the C terminus of Eferin as well as other Rab11/25-binding
proteins, such as Rip11 and nRip11. Using biochemical techniques, we
demonstrated that RBD11 is the region that encodes the specificity for
Rab11/25 but is distinct from the region interacting with the Rab
switch domain, since its interactions with the Rab11/25 are not
GTP-dependent.
Materials and Antibodies--
Cell culture reagents were
obtained from Life Technologies, Inc. unless otherwise specified.
Miscellaneous chemicals were obtained from Sigma. Actin-rhodamine
conjugates were purchased from Molecular Probes (Eugene, OR). Mouse
monoclonal anti-Myc antibody (9E10) was obtained from Santa Cruz
Biotechnology Inc. (Santa Cruz, CA). Fluorescein isothiocyanate-labeled
anti-rabbit IgG and Texas Red-labeled anti-mouse IgG antibodies were
obtained from Jackson ImmunoResearch Laboratories (West Grove, PA).
Cell Culture and Immunofluorescence Microscopy--
Madin-Darby
canine kidney (MDCK II) cells were cultured, and immunofluorescence
microscopy was performed as described previously (16). For
immunofluorescence microscopy, cells were fixed with 4%
paraformaldehyde for 15 min. Cells were then permeabilized in 0.4%
saponin and nonspecific sites blocked with phosphate-buffered saline
containing 0.2% BSA, 0.4% saponin, and 1% bovine serum. Following
incubation with antibodies, samples were extensively washed and mounted
in VectaShield (Vector Laboratories, Burlingame, CA).
Immunofluorescence localization was performed using a Molecular Dynamics laser confocal imaging system (Beckman Center Imaging Facility, Stanford University, Stanford, CA).
MDCK cells were transfected using the LipofectAMINE 2000 system (Life
Technologies Inc.). At 24-h post-transfection, cells were trypsinized
and resuspended in low Ca2+ (5 µM) minimum
Eagle's medium with Earle's salts. 1.6 × 105
cells were seeded into one well of a 24-well collagen-coated Transwell
filter (6.5-mm diameter, 0.4-mm pore size; Corning-Costar Corp.,
Corning, NY). After 5 h, the low Ca2+ medium was
changed to Dulbecco's modified Eagle's medium with 10% fetal bovine
serum. Cells were cultivated for 2-3 days to grow a confluent and
fully polarized cell layer before imaging them with a Bio-Rad laser
confocal imaging system (Beckman Center Imaging Facility, Stanford
University). X-Z views were obtained by averaging sections over a line
at each z position in 0.5 mm steps.
GST and BSA Pull-down Assays--
For pull-down assays, Rab11a
or RBD11 expressed as GST fusion proteins were bound to
glutathione-agarose beads by incubating at room temperature for 1 h. Where indicated, BSA-RBD11 conjugates were bound to Affi-Gel beads
(Bio-Rad) and used for the pull-down assays. Beads were extensively
washed, resuspended in reaction buffer (50 mM Hepes, pH
7.4, 100 mM NaCl, 1 mM MgCl2, and 1 mM dithiothreitol), and incubated either with recombinant
proteins or with HeLa cell Triton X-100 extracts (13). Beads were then extensively washed and binding proteins eluted with 1% SDS. Samples were then separated by SDS-polyacrylamide gel electrophoresis and
analyzed either by Western blotting or Coomassie Blue staining.
Yeast Two-hybrid Screens--
The bait construct was prepared by
sub-cloning full-length Rab25 into the pGBKT7 plasmid. The construct
was used to transform AH109 yeast cells according to the
manufacturer's protocol (CLONTECH, Palo Alto, CA).
A human kidney cDNA library was screened by mating Y187 yeast cells
with AH109 cells expressing Rab25. After incubation for at least
48 h at 30 °C, prominent colonies were spotted onto fresh
double (synthetic dropout media-Trp/-Leu), triple (synthetic dropout
media-Trp/-Leu/-His), and quadruple (synthetic dropout media-Trp/-Leu/-His/-Ade) dropout media and checked for
Eferin Is a Novel Rab11 and Rab25-binding
Protein--
Despite the accumulating evidence implicating
Rab11/25 GTPases in regulating multiple membrane trafficking
pathways, we still know very little about the mechanism of their
function. In an attempt to isolate additional Rab11/25 effectors we
screened a human kidney cDNA library using Rab25 as bait in the
yeast two-hybrid system. This screen resulted in the isolation of 25 cDNA clones that specifically interacted with Rab11 and Rab25. 15 out of 25 clones were identified as KIAA0665, a 759-amino acid open
reading frame of unknown function (17). Amino acid sequence analysis using PROSITE and PFAM revealed that KIAA0665 contains an N-terminal proline-rich region, as well as two EF-hand motifs (Fig.
1B). Thus, we will be
referring to KIAA0665 as Eferin (AF395731), an
EF-hands-containing
Rab11/25-interacting protein.
All Eferin clones isolated from the yeast two-hybrid screen encoded the
C terminus of Eferin with the smallest clone spanning amino acid
residues 665-756. The Eferin-(665-756) motif was sufficient to
exhibit specific binding to Rab11 and Rab25 but not Rab17 and Sec8
(Fig. 1A). Furthermore, binding to Rab11 was
GTP-dependent since Eferin-(665-756) failed to bind
Rab11-S25N (Fig. 1A). Eferin and Rab11/25 interactions were
not restricted to the yeast two-hybrid system because Myc-Eferin
co-precipitated with Rab25-GFP in a GTP-dependent manner
from transiently transfected COS cells (see Fig. 3D). In
addition, Rab11b but not Rab1, Rab2, or Rab3a could be precipitated
using agarose beads coated with GST-Eferin-(665-756) (data not shown).
To determine whether Eferin co-localizes with Rab11 in living cells, we
transiently co-transfected normal rat kidney (NRK) cells with
Eferin-GFP and Myc-Rab11a cDNAs. As shown in Fig. 1, C
and D, Eferin-GFP shows a predominately perinuclear
staining, reminiscent of recycling endosomes and the
trans-Golgi network (Fig. 1C) and largely
overlapping with Myc-Rab11a (Fig. 1D). Furthermore, immunofluorescence studies using transiently transfected MDCK cells
showed that, similarly to Rab11, in epithelial cells Eferin-GFP is
localized to the apical pole (Fig. 1E).
Identification of a Novel Rab11 Binding Domain (RBD11) Present in
Rip and Eferin Proteins--
In addition to Eferin, the yeast
two-hybrid screen yielded 10 other clones that specifically interacted
with Rab11 and Rab25. Seven of these clones encode fragments of Rip11
(AF334812), while the other three were identified as nRip11 (AY037299). Rip11 (13) and nRip112 are
previously identified related Rab11/25-binding proteins. The data from
the yeast two-hybrid screens (Fig. 1, A and B)
demonstrate that the information necessary to ensure Rab specificity
and GTP dependence is encoded within the last C-terminal 86 amino acids of Rip proteins. This result was somewhat unexpected, since we have
previously reported that Rip11 also binds to Rab11a through the middle
region of the protein (Rip11-(200-507)) (13). To test whether both
regions of Rip11 are involved in association with Rab11, we performed
GST-Rab11a pull-down assays using in vitro translated
fragments of Rip11 and nRip11. As shown in Fig. 2C, the binding of
Rip11-(200-507) is much weaker compared with that of Rip11-(507-653).
Furthermore, the region in nRip11 equivalent to Rip11-(200-507) failed
to bind to GST-Rab11a (Fig. 2C), indicating that the primary
Rab11/25 binding domain is likely located within the C-terminal domains
of Rip11 and nRip11. Further experiments, however, will be necessary to
determine the role of Rip11-(200-507) in Rab11/25 binding to
Rip11.
Despite the fact that Eferin and Rips are not related proteins, the
alignment of Rab11/25-interacting domains revealed that Eferin, Rip11,
and nRip11 contain a highly conserved domain of 20 amino acids at the
very C terminus of the protein (Fig.
3A). Deletion of these
residues in Rip11 and Eferin resulted in loss of binding to Rab11
(Figs. 2C and 3B), suggesting that these amino acid residues might directly participate in Rab11/25 binding. To
address that possibility we synthesized the peptide corresponding to
Rip11-(628-645) (Rab11/25 binding
domain, RBD11) and used it in competition assays. As shown
in Fig. 3C, while the Rip11 N-terminal peptide (amino acids
1-17) had no effect on Rip11 binding to GST-Rab11a, the addition of
RBD11 partially inhibited Rip11/Rab11 interaction. Furthermore, RBD11
also plays a role in Eferin binding to Rab11/25 since it inhibits
Myc-Eferin co-precipitation with Rab25-GFP (Fig. 3D).
While our data suggest that RBD11 is involved in Rab11/25 binding
in vitro, it remains to be determined whether it is involved in Rip11 trafficking in living cells. To address that issue we transiently transfected MDCK cells with GFP fused to either full-length Rip11 (Rip11-GFP), or Rip11 lacking the RBD11 domain
(Rip11 RBD11 Is Necessary and Sufficient to Mediate Specific Interactions
between Rip11 and Rab11--
The data presented above demonstrate that
RBD11 is necessary for Rab11/25 binding to Eferin and Rip proteins. To
determine whether RBD11 is sufficient for Rab-specific and
GTP-dependent Rab11/25 binding, the peptides corresponding
to either Rip11-RBD11 or Rip11-(1-17) (Fig. 5A,
N pept) were conjugated to BSA-coated agarose
beads and used in Rab11 pull-down assays. As shown in Fig.
5A, while Rab11 did not
co-sediment with BSA alone or BSA-N pept, it bound to BSA-RBD11. The
binding was specific since it was observed only with Rab11a (Fig.
5B) and Rab11b (data not shown) but not Rab1a and Rab3a.
Furthermore, the BSA-RBD11/Rab11a interactions could be inhibited with
soluble RBD11 in a concentration-dependent manner (Fig.
5C). To test whether full-length RBD11 is necessary for
Rab11/25 interactions, we expressed RBD11 as a GST fusion protein. In
agreement with data reported above, Rab11a also interacted with
GST-RBD11. Truncations of the RBD11 motif resulted in decreased Rab11a
binding, suggesting that intact RBD11 is necessary for binding to Rab
GTPases (Fig. 5E). Surprisingly, while BSA-RBD11 specifically interacted with Rab11/25 proteins, it showed no GTP dependence (Fig. 5D). Perhaps, RBD11 determines Rab
specificity by interacting with RabCDR, while additional motifs
interacting with Rab switch I/II domains are responsible for the
GTP-dependent component.
Rab11 is a small GTPase that was implicated in regulating a
variety of distinct membrane trafficking steps (8-10). However, the
molecular mechanisms involved in regulation and determining the
specificity of Rab11 functions remain to be understood. The ever
growing number of Rab11-binding proteins suggests that sequential or
competitive interactions of Rab11 with different effector proteins might account for the diversity of Rab11 functions. In this study, we
have identified a novel Rab11/25-interacting protein and named it
Eferin. Several lines of evidence suggest that Eferin is an effector
for Rab11/25 GTPases. First, Eferin binds specifically to Rab11/25 but
not other Rabs. Second, Eferin preferentially associates with the
GTP-bound, thus active, form of Rab11. Third, Eferin co-localizes with
Rab11 and Rab25 (data not shown). Thus, our data suggest that Eferin is
an effector protein for Rab11/25 GTPases, although its role in membrane
trafficking remains to be elucidated.
Immunofluorescence studies using transiently transfected MDCK cells
showed that Eferin-GFP is localized exclusively to the apical plasma
membrane, suggesting that Eferin might be involved in regulation of
apical targeting. Interestingly, besides EF-hands, Eferin also contains
a region resembling the C-terminal domain of the ezrin/radixin/moesin
protein family, also known as ERM proteins, which also localize near
the apical plasma membrane in actin-rich cytoskeletal structures
(18-20). ERM proteins can form homo- and heterodimers via C-terminal
interactions with the N-terminal FERM domain (21). The
FERM/C-terminal interaction masks the binding sites for other
molecules, in this way regulating ERM protein association with the
cytoskeleton (22). Thus, it is tempting to speculate that the
Rab11-Eferin complex might interact with the FERM domain of the ERM
proteins, in this way regulating ERM protein activity and cross-linking
membranes to the cytoskeleton.
The ever growing Rab11 binding protein family already includes
five members. The ability to interact with several effector proteins
seems to be a common feature of many Rab GTPases (23). The main
challenge of future studies will be to determine the functions of all
of these proteins, as well as to understand the mechanisms of their
interactions with Rab proteins. Indeed, it remains unclear whether the
effector proteins compete with each other for binding to Rabs or work
in a consecutive fashion. The work presented here suggests that Rips
and Eferin compete for interactions with Rab11/25. Indeed,
identification of a common Rab11/25 binding domain indicates that
Eferin and Rips use the same binding site on Rab11/25. Interestingly,
RBD11 is not present in the other known Rab11/25 effector proteins,
such as myosin Vb and Rab11BP/rabphilin-11 (12, 14, 15). It will be
interesting to see whether these proteins can actually co-bind to
Rab11/25 with either Eferin or Rips, perhaps forming signaling
complexes that regulate transport vesicle trafficking.
While RBD11 appears to be involved in determining the specificity of
interactions with Rab GTPases, its binding is independent of GTP.
Perhaps, RBD11 is an equivalent of a SGAWFF motif in
rabphilin-3a, which interacts with Rab3a CDRs (7). If this is
the case additional motifs will be required to interact with Rab switch
I/II domains to provide the GTP-dependent component of
binding. Thus, it is likely that Eferin and Rip proteins interact with
Rab11/25 via several motifs. At least some of the GTP-sensing motifs
are encoded within the 60-amino acid domain located upstream of RBD11.
Interestingly, while the putative GTP-sensing regions in Rip11 and
nRip11 are very highly conserved, they have no apparent homology to
Eferin. Thus Rip and Eferin proteins share the common motif involved in Rab11/25 recognition but may use different mechanisms for mediating the
GTP-dependent component of Rab11/25 binding.
The functional significance of the differences in Rip and Eferin
interactions with Rab11/25 remains to be determined. One possibility is
that additional cellular factors can regulate the affinity of Rab11/25
binding to its effectors. Indeed, the recombinant full-length Rip11
binds poorly to Rab11a in pull-down and yeast two-hybrid assays as
compared with full-length endogenous Rip11 from cellular TX-100
extracts (data not shown). Furthermore, it has been previously shown
that Rip11 can also interact with Despite the recent progress in understanding the roles of Rabs and
their effectors in regulating membrane trafficking, we are only
beginning to unravel the structural determinants of their function.
Identification and characterization of the Rab11/25 binding regions in
Rip and Eferin proteins will be of crucial importance in understanding
the molecular mechanisms involved in differential regulation of the
variety of Rab11-dependent trafficking pathways.
We thank Dr. Susan L. Palmieri (Stanford
University, cell imaging facility) for assistance with confocal
microscopy. We are grateful to Dr. T. Nagase for providing cDNA
encoding KIAA0665 (Eferin). We also thank Dr. Suzie Scales for the
critical reading of the manuscript.
*
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.
The nucleotide sequence(s) reported in this paper has been submitted to the GenBankTM/EMBL Data Bank with accession number(s) AF395731.
§
Present address: Dept. of Cellular and Structural Biology,
University of Colorado Health Sciences Center, Rm. 4535, Denver, CO 80262.
Published, JBC Papers in Press, July 31, 2001, DOI 10.1074/jbc.M106133200
2
R. Prekeris and R. H. Scheller, unpublished data.
The abbreviations used are:
CDRs, complementary-determining regions;
RBD, Rab binding domain;
MDCK, Madin-Darby canine kidney;
BSA, bovine serum albumin;
GST, glutathione
S-transferase;
ERM, ezrin/radixin/moesin;
GTP
Identification of a Novel Rab11/25 Binding Domain Present in
Eferin and Rip Proteins*
§,, and¶
Howard Hughes Medical Institute, Department
of Molecular and Cellular Physiology, Stanford University School of
Medicine, Stanford, California 94305-5428 and ¶ Genentech Inc.,
South San Francisco, California 94080-4990
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
3/
5 loop (5, 6). Indeed, the recently reported structure of Rab3a bound to a putative effector, rabphilin-3a, revealed that the Rab3a-rabphilin-3a complex interacts through two main regions (7). The first consists of conformationally sensitive switch regions of Rab3a bound to the a1 helix and the C-terminal part of
rabphilin-3a. The second involves the SGAWFF domain of rabphilin-3a, which fits into a pocket formed by the three hypervariable
complementary determining regions
(CDRs)1 of Rab3a,
corresponding to the N and C termini and the 3/5 loop. Thus, it
appears that the hypervariable RabCDR is involved in determining the
specificity of effector binding, while the conserved switch regions
impart GTP dependence and binding. It remains to be determined,
however, whether this paradigm also applies to other Rab-effector complexes.
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-galactosidase expression by the X-gal filter assay. DNA from each
positive clone was extracted and sequenced. As a further test to
eliminate false positives, isolated prey vectors were co-transformed
with bait plasmids and checked again for reporter gene expression. For
protein interaction studies, a series of bait constructs was prepared using the following cDNA: Rab11 wild-type, Rab11-S25N, Rab17, Rab25, and Sec8. For prey constructs, the following cDNA were inserted into pAct2: Rip11-(566-653), nRip11-(425-511), and
Eferin-(665-756). AH109 yeast was pairwise co-transformed with bait
and prey constructs and grown on double dropout media. Clones were
transferred to increasingly stringent selection media as described
above. Images of colony growth were obtained using a Linotype-Hell
transparency scanner in conjunction with Adobe Photoshop.
RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
View larger version (27K):
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Fig. 1.
Identification of a novel Rab11/25-binding
protein. A, to measure the interactions between Eferin
and various Rabs, the two-hybrid system was used as described in
"Experimental Procedures." Yeast were plated on double
(His+) or triple (His 
) selection plates.
Rab11S is the dominant negative Rab11-S25N mutant.
B, schematic representation of the structure of Eferin.
Pro-Rich, proline-rich region; EF, EF-hand motif;
and ERM like, ezrin/radixin/moesin domain. The nucleotide
sequence of human Eferin has been submitted to GenBankTM
with accession no. AF395731. C-E, to analyze the
subcellular localization of Eferin, normal rat kidney (C and
D) or polarized MDCK (E) cells were transfected
with Eferin-GFP (C and E, green) and
stained for Rab11a (D) or actin (E,
red); bars, 2 µm.
View larger version (21K):
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Fig. 2.
The role of Rip11 and nRip11 C terminus in
binding to Rab11/25. A and B, to measure the
interactions between nRip11 (A) and Rip11 (B) to
various Rabs, the MATCHMAKER two-hybrid system
(CLONTECH) was used. Rabs were cloned into
pGBKT7-BD (bait) while nRip11-(425-511) and Rip11-(566-653) were
cloned in pACT2-AD (prey). Clones were then co-transfected into AH109
yeast and plated on double (His+) or triple
(His ) selection plates. Rab11S is the dominant negative
Rab11-S25N mutant. C, different Rip11 and nRip11 fragments
were Myc-tagged by cloning into a pCMV Tag3a vector (Stratagene, La
Jolla, CA). Myc-tagged proteins were then in vitro
translated in the presence of [35S]methionine and bound
to glutathione beads coated with either GST alone or GST-Rab11a. The
amount of Rip11 or nRip11 bound was measured using a Molecular Dynamics
PhosphorImager scanner and expressed as a percentage of total protein
used in the assay. The data presented is the mean of two independent
experiments.
View larger version (33K):
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Fig. 3.
Identification of the RBD11 conserved in Rip
and Eferin proteins. A, amino acid sequence alignment
of a putative RBD11 from human Rip11 (Rip11, accession no.
AF334812), human nRip11 (nRip11, accession no. AY037299),
Eferin (Eferin, accession no. AF395731),
Drosophila Rip11 (dRip11, accession no.
AE003509), and mouse Rip11 (mRip11, accession no. AK014696).
Clear boxed regions show conserved amino acids in RBD11.
Gray boxed regions show amino acids conserved only in Rip
proteins. B, to determine whether RBD11 is necessary for
Eferin and Rip11 interactions with Rab11/25, Eferin-(665-756),
Eferin-(665-736), Rip11-(566-653), and Rip11-(566-627) (prey) were
co-transfected with Rab11a (bait) into AH109 yeast. Yeast cells were
then plated on double (His+) or triple (His )
selection plates. C, glutathione-Sepharose beads loaded with
either GST alone (GST) or GST-Rab11a (Rab11a)
were incubated with Caco2 cell lysates in the presence of 1 mM GTP
S and 100 µg/ml Rip11-(1-17) (N
pept) or 100 mg/ml Rip11-(628-645) (RBD11).
Bound proteins were then eluted with SDS sample buffer and
immunoblotted for the presence of Rip11; PNS, Caco2 cell
postnuclear supernatant. D, to test for the role of RBD11 in
Eferin and Rab25 interaction in mammalian cells, we transiently
co-transfected COS cells with Myc-Eferin and Rab25-GFP. Rab25-GFP was
immunoprecipitated from COS cell Triton X-100 lysates in the presence
of GTPS, GTPS, or GTPS with 100 µg/ml Rip11-(628-645)
(RBD). Samples were then immunoblotted for the presence of
Myc-Eferin.
RBD11-GFP) (Fig. 4). As
previously reported (13), in non-polarized MDCK cells Rip11-GFP was
localized to perinuclear endosomes, which also contained Rab11a (Fig.
4, A-C). Furthermore, in polarized MDCK cells,
Rip11-GFP was present at the apical pole of the cell, suggesting that
GFP tagging did not affect the Rip11 subcellular distribution (Fig. 4,
G-I). Deletion of RBD11, on the other hand, dramatically affected the subcellular distribution of Rip11-GFP. As
shown in Fig. 4, D-F, in non-polarized cells
Rip11RBD11-GFP is present predominately on the plasma membrane and
shows no co-localization with Rab11a-containing endosomes. Furthermore,
in polarized cells Rip11RBD11-GFP has lost its polarized
distribution and is present throughout the entire cell (Fig. 4,
J--L). As in non-polarized cells, a large portion
of Rip11RBD11-GFP is present on the plasma membrane, although some
Rip11RBD11-GFP also shows cytosolic staining (Fig.
4J).
View larger version (42K):
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Fig. 4.
The role of RBD11 in Rip11 subcellular
localization. To analyze subcellular localization of Rip11 and
Rip11 RBD11 in epithelial cells, MDCK cells were transfected with
either Rip11-GFP (A and G) or Rip11RBD11-GFP
(D and J) and plated at low density on
collagen-coated glass coverslips (non-polarized)
(A-F). To obtain polarized MDCK cells, cells
were plated on Transwell filters and grown for 72 h before imaging
(G and L). For imaging, cells were fixed and
permeabilized with saponin and then stained for Rab11a (B
and E) or actin (H and K).
C, F, I, and L are the
merged images with yellow representing areas of overlap.
G-L shows both X-Y and
X-Z planes of the same cells; bars, 2 µm.
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Fig. 5.
RBD11 is necessary and sufficient to mediate
specific interactions between Rip11 and Rab11.
A-D, for protein pull-down assays using
Affi-Bead conjugates, RBD11 peptide was attached to Affi-Beads using
Imject maleimide-activated BSA (Pierce). After incubation with
different Rab GTPases, beads were washed, and bound proteins analyzed
by SDS-polyacrylamide gel electrophoresis and Coomassie Blue staining.
Start represents 20% of the recombinant protein used in the
assay. A, purified recombinant Rab11a was incubated with
Affi-Beads loaded with BSA alone (BSA), BSA-Rip11-(1-25)
(BSA-N pept), or BSA-RBD11 (BSA-RBD)
in the presence of 1 mM GTP S.
B-C, to determine the specificity of Rab11
binding to RBD11, Affi-Beads-BSA (BSA) or
Affi-Beads-BSA/RBD11 (BSA-RBD) were incubated either with 50 µg of Rab1a, Rab3a, or Rab11a in the absence (B) or
presence of varying concentrations of soluble RBD11 (C).
Bound proteins were analyzed as described above. D, to
analyze the GTP dependence of Rab11 binding to RBD11, varying
concentrations of Rab11a were incubated with Affi-Beads conjugated to
BSA-RBD11 in the presence of either GTPS (top
row) or GDPS (bottom row).
E, to further map the RBD11 binding domain, DNA coding for
wild-type Rip11-RBD11 and several RBD11 truncation/deletion mutants
were fused to GST. Fusion proteins were purified and used in GST
pull-down assays to determine their ability to bind recombinant Rab11a.
Recombinant Rab11a was bound for 1 h at 4 °C to glutathione
beads coated with equal amounts of various GST-RBD11 constructs. The
beads were then washed and samples eluted with 1% SDS, followed by
separation on SDS-polyacrylamide gels and staining with Coomassie Blue.
Gels were then scanned, and the amount of Rab11a bound was determined
using IQMac v1.2 software. The values were expressed as a
percentage of Rab11a bound to wild type GST-RBD11 fusion protein.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
SNAP and cytoskeleton (13,
24). Thus, the interactions of Rips and Eferin with different factors
could be used as a means of differentially regulating Rab11/25 binding.
Alternatively, the Rab11/25 binding motif in Eferin and Rip11 might be
conformationally hidden and require activation before binding to
Rab11/25. We have previously demonstrated that phosphorylation of Rip11
plays an important role in its trafficking (13). Thus, differential
phosphorylation on Rab11/25 binding motifs could also play a role in
regulating the binding of Rip11 and Eferin to Rab GTPases.
ACKNOWLEDGEMENTS
FOOTNOTES
To whom correspondence should be addressed: Genentech Inc., 1 DNA Way, South San Francisco, CA 94080-4990. Tel.: 650-225-4952; Fax:
650-225-4265; E-mail: scheller@gene.com.
ABBREVIATIONS
S, guanosine
5'-2-O-(thio)triphosphate;
GTPS, guanosine
5'-3-O-(thio)triphosphate;
GFP, green fluorescent protein;
X
gal, 5-bromo-4-chloro-3-indolyl--D-galactopyranoside.
REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
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