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J. Biol. Chem., Vol. 276, Issue 35, 32875-32882, August 31, 2001
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From the Institute of Molecular and Cell Biology, 30 Medical Drive,
Singapore 117609, Republic of Singapore
Received for publication, November 16, 2000, and in revised form, May 31, 2001
Protein of regenerating liver (PRL)-1, -2, and -3 comprise a subgroup of closely related protein-tyrosine phosphatases
featuring a C-terminal prenylation motif conforming to either the
consensus sequence for farnesylation, CAAX, or
geranylgeranylation, CCXX. Yeast two-hybrid screening for
PRL-2-interacting proteins identified the Protein prenylation is a post-translational modification with an
important role in targeting proteins to membranes and in protein-protein interactions (reviewed in Refs. 1 and 2). Prominent
among a variety of prenylated proteins are numerous small GTP-binding
proteins, including Ras, RhoB, and the Rab proteins, and prenylation is
essential for their cellular functions in signal transduction and
vesicle trafficking (2). Isoprenoid modification can be catalyzed by
one of three different transferases, depending on the isoprenoid and
the prenylation motif of the target protein. Farnesyltransferase
(FT)1 and
geranylgeranyltransferase I (GGT I) are Ras oncogenes are associated with many human cancers, and as Ras
transforming function requires farnesylation (12, 13), FT inhibitors
(FTI) have been developed and tested as anti-cancer therapeutics. While
Ras-mediated oncogenesis is in many cases compromised by such
inhibitors (14-17), in other cases it appears that other non-Ras
farnesylated proteins are the effective targets of the inhibitor (18).
One candidate is RhoB, which is farnesylated and geranylgeranylated in
cells, and a gain in the level of geranylgeranylated RhoB is observed
upon FTI treatment (19, 20). This prenylation switch has been proposed
to mediate a gain of the tumor growth inhibitory function of RhoB (21),
however, recent studies with human cancer cells suggest that both
prenylated forms of RhoB are potent anti-transforming molecules and
that RhoB thus may not be the unidentified FTI target in cancer cells
(22). The nature and role of other farnesylated proteins that could
account for the anti-tumorigenic effects of FTI need to be investigated.
The PRL subgroup (PRL-1, -2, -3) of protein-tyrosine phosphatases
(PTPs) are closely related intracellular enzymes (23-27) with the
highest sequence homology to two dual specificity PTPs, Cdc14p and
PTEN. The PRLs are unique among PTP superfamily members in possessing a
C-terminal prenylation motif and being prenylated in vivo.
Prenylated PRLs are found in the early endosome and at the plasma
membrane (28). Inhibition of prenylation, by treatment of cells with a
farnesyltransferase inhibitor, results in PRL translocation to the
nucleus (28). The prenylation motifs of the PRLs (CCIQ, CCVQ, CCVM)
conform to either the CAAX motif preferentially recognized
by FT or to the CCXX motif recognized by GGT II, although their relocalization in response to FT inhibition indicates that they
are likely farnesylated proteins in vivo. The
prenylation-dependent subcellular localization of the PRLs
suggests that regulated prenylation is a mechanism which controls the
access of these PTPs to early endosomal or nuclear substrates. Cellular
substrates of the PRL phosphatases have not yet been identified,
although PRL-1 interacts with a basic leucine zipper protein, ATF-7,
and can dephosphorylate it in vitro (29).
Although the specific substrates of the PRLs are unknown, PRL
expression is associated with two distinct cell processes. PRL-1 was
first identified as an immediate early gene expressed in regenerating liver and in serum-treated fibroblasts, and overexpression of PRL-1 in
NIH 3T3 cells results in cell transformation, suggesting that the gene
product plays a role in proliferation (23, 30). Another role for PRL-1
has been proposed in the development and maintenance of differentiating
epithelial tissues, as it is expressed in several developing tissues in
fetal rat, and in the adult rat is found in terminally differentiated
cells such as renal tubular epithelium, bronchiolar epithelium of the
lung, and in villus but not crypt enterocytes of the intestine (31,
32). Similarly, PRL-3 is specifically expressed in the differentiated
epithelial cells of the villus but not in the proliferating crypt cells
of the mouse small intestine (28).
Yeast-two hybrid screening was carried out to identify PRL-2
interacting proteins, the nature of which could give insight into the
cellular role of this PTP. The Expression Plasmids--
The pAS2-1 vector
(CLONTECH) was used to generate the yeast
expression PRL-PTP plasmids. In general, the cDNAs encoding the full-length PRL-1, -2, and -3 were amplified by polymerase chain reaction, and each subcloned in-frame into BamHI and
PstI cut pAS2-1 vector. The pXJ40-myc vector (a gift from V. Yu) was used to generate the PRL-PTP expression plasmids for use in
transient transfections. A BamHI-XhoI fragment
encoding each full-length PRL-PTP or a mutant PRL-2 lacking the four
C-terminal amino acids (PRL-2(cd)) was excised from pGEX-KG-PRL-1, -2, -3 or pGEX-KG-PRL-2(cd) (28), respectively, and subcloned in-frame into
pXJ40-myc. The plasmid pXJ40-myc-PRL-2(CSVQ) was generated by in-frame
insertion into BamHI/XhoI-cut pXJ40-myc of a
polymerase chain reaction fragment from amplification of PRL-2 using an
appropriate forward primer incorporating a BamHI site, and a
reverse primer with a nucleotide substitution giving the desired C165S
mutation and an engineered XhoI site. To generate the
PRL-1/-2 chimera expression plasmids, a PRL-1 or PRL-2 cDNA
fragment was excised from pXJ40-myc-PRL-2 or pXJ40-myc-PRL-1 at
EcoRII and/or AflII sites, and was replaced by
the corresponding fragment from the other PRL-PTP. The Yeast Two-hybrid System--
The interaction screen was
performed essentially as recommended in the
CLONTECH user manual. A HeLa cDNA library
(CLONTECH) was transformed into the yeast strain
Y190, which had been pretransformed with pAS2-1-PRL-2. The
transformants were plated on His, Leu, and Trp Cell Culture and Transient Transfections--
HeLa cells were
maintained in Dulbecco's modified Eagle's medium and transiently
transfected using LipofectAMINE reagent (Life Technologies, Inc.). The
empty expression vector pXJ40-myc was used to normalize the amount of
DNA in each transfection. After 24 h of culture, the cells were
harvested in lysis buffer (50 mM Tris, pH 7.5, 150 mM NaCl, 10 mM MgCl2, 2 mM phenylmethylsulfonyl fluoride). The cytosol fraction was
prepared by passing the cells 6-8 times through a 26-gauge needle,
followed by clarification of the lysate by centrifugation at 12,000 rpm
for 30 min at 4 °C. The supernatant (cytosol) was used for
immunoprecipitation and Western blotting. For farnesyltransferase
inhibition, 10 µM FTI-277 (a gift from S. M. Sebti)
(33) in Dulbecco's modified Eagle's medium, 10% fetal calf
serum was added to the cells 5 h after transfection.
Western Blots, Immunoprecipitation, and
Immunofluorescence--
Anti-Myc (9E10, Santa Cruz) and anti-FLAG (M2,
Sigma) antibodies were used for immunoprecipitation and Western
blotting. Typically the lysates were incubated with the specific
antibody overnight at 4 °C. Immunofluorescence was carried out using
fluorescein isothiocyanate-conjugated Myc antibody as described
(28).
In Vitro GGT II Assay--
HeLa cells were transiently
transfected with pXJ40-myc vector (mock) or pXJ40-myc-PRL-2 (PRL-2) for
18 h prior to harvest. Cell lysate was prepared by scraping the
cells into lysis buffer containing 50 mM HEPES, pH 7.5, 150 mM NaCl, 10 mM MgCl2, 10 mM dithiothreitol, 2 mM phenylmethylsulfonyl
fluoride and then passing the cells 6-8 times through a 26-gauge
needle. The lysate was clarified by centrifugation at 12,000 rpm for 30 min at 4 °C, and the supernatant was used as the source of GGT II.
The in vitro enzymatic reaction was initiated by adding 80 µg of cell lysate to buffer (50 mM Hepes, pH 7.5, 150 mM NaCl, 10 mM MgCl2, 10 mM dithiothreitol) containing 2 µM
[3H]GGPP (22 Ci/mmol, PerkinElmer Life Sciences) and with
or without 2 µM Rab3a protein (Calbiochem). The 50-µl
reaction was incubated at 30 °C and stopped after 4 h by adding
SDS sample buffer, and then resolved by SDS-PAGE. The gel was dried and
exposed to hyperfilm at Metabolic Labeling and
HPLC--
1-[3H]Mevalonolactone (40 Ci/mmol,
[3H]MVA) was purchased from PerkinElmer Life Sciences.
HeLa cells were maintained and transfected with pXJ40-myc-PRL-2, and
treated with or without FTI-277, as described above. For the final
18 h, cells were treated with [3H]MVA at 100 µCi/ml and 30 µM lovastatin (Calbiochem). Cell lysate was prepared by scraping the cells into 50 mM Tris, pH 7.5, 150 mM NaCl, 10 mM MgCl2, 1%
Triton X-100, 2 mM phenylmethylsulfonyl fluoride and then
passing the cells 6-8 times through a 26-gauge needle. The lysate was
clarified by centrifugation at 12,000 rpm for 30 min at 4 °C, and
the supernatant was used to isolate myc-PRL-2 by immunoprecipitation
with anti-Myc antibody (9E10, Santa Cruz). The immunoprecipitate was
washed twice with acetone and CHCl3/MeOH, 1:2 (v/v) at
Physical Association of PRL-2 with GGT II
PRL-2 is a member of a group of three closely related proteins which
also includes PRL-1 and PRL-3 (23-27). In order to test the
specificity of the interaction of PRL-2 with the
To validate the yeast two-hybrid results, we examined the in
vivo interaction of PRL-2, -1, or -3 and PRL-2 and GGT II
To determine whether the linked properties of PRL-2 prenylation status
and subcellular localization affect its interaction with GGT II,
co-immunoprecipitation experiments were carried out from lysates of
HeLa cells expressing FLAG-tagged
To distinguish between these latter possibilities, we investigated the
association between PRL-2 Is Not a Substrate for GGT II--
It is well documented
that GGT II is a prenyltransferase that recognizes the prenylation
motifs of XXCC, CXC, or CCXX, and whose exclusive substrates are Rab GTPases (1). The C-terminal prenylation motif of PRL-2, CCVQ, fits the CCXX sequence
recognized by geranylgeranyltransferase II or the CAAX motif
recognized by farnesyltransferase or GGT I. Indeed, PRL-2 can be
geranylgeranylated or farnesylated in vitro (25, 28). To
examine the possibility that prenylation of PRL-2 by GGT II was
involved in the interaction of these proteins, we examined the lipid
modification of PRL-2 in vivo. HeLa cells transiently
expressing Myc-tagged PRL-2 were labeled with the isoprenoid precursor
[3H]mevalonolactone, and isoprenoid analysis of the
immunoprecipitated PRL-2 carried out. SDS-PAGE and autoradiography of
the PRL-2 immunoprecipitate revealed that PRL-2 was labeled, and that
it contained the majority of the label in the immunoprecipitate (Fig.
5A, lane 2). A duplicate Myc-PRL-2 immunoprecipitate was processed for isoprenoid analysis, and
the sample resolved by HPLC reverse phase chromatography. The
3H in the collected fractions was quantitated, and the
major labeled elution peak was found to co-migrate with an authentic
trans,trans-farnesol standard (Fig. 5B). No
obvious labeled elution peak co-migrated with an authentic
all-trans-geranylgeraniol standard. Thus PRL-2 is normally
farnesylated, and not geranylgeranylated, in vivo. Treatment
of PRL-2 expressing cells with the farnesyltransferase inhibitor
FTI-277 results in relocalization of PRL-2 from the early endosome to
the nucleus (28). Inhibition of farnesylation sometimes results in a
gain in geranylgeranylation (8, 9, 20), and we examined if this
occurred with PRL-2. Using the HeLa cell expression and labeling system
as above, cells were treated with or without FTI-277 and the isoprenoid
content of the immunoprecipitated PRL-2 was analyzed. As expected,
PRL-2 was labeled in the absence of FTI-277 and the major elution peak co-migrated with authentic trans,trans-farnesol standard.
FTI-277 treatment resulted in the absence of labeled PRL-2 in the PRL-2 immunoprecipitate PRL-2 (Fig. 5A, lane 4) and in the
disappearance of the elution peak co-migrating with
trans,trans-farnesol (Fig. 5C). No obvious
elution peak co-migrated with the authentic
all-trans-geranylgeraniol standard. Moreover, co-expression
of ectopically tagged
Another approach was also employed to test whether PRL-2
geranylgeranylation by GGT II or recognition of a Rab-like prenylation motif in PRL-2 (CCXX) was involved in the interaction with
The C-terminal Region of PRL-2 Is Required for Association with
The GGT II PRL-2 Expression Inhibits Endogenous GGT II Activity--
The
above results predict that increasing the amount of PRL-2 in the cell
might favor the formation of the PRL-2· The phosphatase PRL-2 is physically associated with The crystal structure of GGT II shows that the In light of the requirement for the Among the family of PRLs, only PRL-2 can interact with We thank S. M. Sebti (Moffitt Cancer
Center, Tampa, FL) for the gift of FTI-277, M. C. Seabra (Imperial
College School of Medicine, London, United Kingdom) for the *
This work was supported by the National Science and
Technology Board of Singapore.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.
Published, JBC Papers in Press, July 10, 2001, DOI 10.1074/jbc.M010400200
2
X. Si, Q. Zeng, C. H. Ng, W. Hong
and C. J. Pallen, unpublished observations.
The abbreviations used are:
FT, farnesyltransferase;
FTI, farnesyltransferase inhibitor;
GGT, geranylgeranyltransferase;
PTP, protein-tyrosine phosphatase;
PRL-PTP, protein of regenerating liver-protein-tyrosine phosphatase;
HPLC, high
performance liquid chromatography;
PAGE, polyacrylamide gel
electrophoresis.
Interaction of Farnesylated PRL-2, a Protein-tyrosine
Phosphatase, with the
-Subunit of Geranylgeranyltransferase II*
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-subunit of Rab
geranylgeranyltransferase II (GGT II). The specific interaction of
GGT II with PRL-2 but not with PRL-1 or -3 occurred in yeast and
HeLa cells. Chimeric PRL-1/-2 molecules were tested for their
interaction with GGT II, and revealed that the C-terminal region of
PRL-2 is required for interaction, possibly the PRL variable region
immediately preceeding the CAAX box. Additionally, PRL-2
prenylation is prequisite for GGT II binding. As prenylated PRL-2 is
localized to the early endosome, we propose that this is where the
interaction occurs. PRL-2 is not a substrate for GGT II, as
isoprenoid analysis showed that PRL-2 was solely farnesylated in
vivo. Co-expression of the 
-subunit () of GGT II, GGT
II, and PRL-2 resulted in /GGT II heterodimer formation and
prevented PRL-2 binding. Expression of PRL-2 alone inhibited the
endogenous /GGT II activity in HeLa cells. Together, these
results indicate that the binding of GGT II and PRL-2 to GGT II
is mutually exclusive, and suggest that PRL-2 may function as a
regulator of GGT II activity.
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
/ heterodimers which
share a common -subunit and utilize the C15 farnesyl or the C20
geranylgeranyl, respectively (3-5). Both recognize the prenylation
motif CAAX, where C is cysteine, A is aliphatic,
and X is preferred as Met, Ser of Gln by FT, and as Leu for
GGT I. Ras and Rho proteins can be farnesylated by FT or
geranylgeranylated by GGT I (6-9). The Rab proteins are the only known
substrates of GGT II, a distinct / dimer that prenylates
XXCC, XCXC, or CCXX
C-terminal sequences when the Rab proteins are bound to a carrier
called REP (Rab escort protein) (10, 11).
-subunit of a prenyltransferase, GGT
II, was found to specifically interact with PRL-2. This was intriguing,
as this enzyme is only known to prenylate Rab proteins. The association
of GGT II with PRL-2 in mammalian cells was confirmed, and found to
depend on the prenylation status of PRL-2, even though PRL-2 was
farnesylated in cells. Association also required a unique region of
PRL-2 that is not present in PRL-1 or -3. We present evidence that the
binding of PRL-2 and GGT II to GGT II is mutually exclusive, and
propose that through displacement of GGT II, PRL-2 may function as a
regulator of Rab GGT II activity.
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
GGT II
cDNA (lacking the nucleotides encoding the four N-terminal amino
acids) was amplified from the pGADGH-GGT II-B plasmid and subcloned
into an NcoI/XhoI-cut pGEX-KG vector. The GGT
II cDNA was then excised using NcoI and SacI
flanking sites, and subcloned into an
NcoI/SacI-cut pBKS-flag vector (a gift from S. Lin). The DNA encoding flag-GGT II was released by digestion with
EcoRI and SacI, and subcloned in-frame into pXJ40
to create pXJ40-flag-GGT II. The rat GGT II cDNA was a gift
from M. C. Seabra and was subcloned in-frame into a
BamHI/KpnI cut pXJ41-HA vector. All of the
plasmids were sequenced prior to use.
medium containing 25 mM 3-amino-1,2,4-triazole (Sigma). Plasmids were isolated
from positive colonies that fulfilled all criteria, and retested. One
plasmid that was consistently positive for interaction with PRL-2 was
sequenced and compared against the Entrez data base using a Blast
search, and was identified as the cDNA encoding the -subunit of
human GGT II.
80 °C for 2 weeks and the labeled Rab3a
protein was quantified by densitometry.
20 °C, dried by vacuum centrifugation, and processed for
isoprenoid analysis as described by Casey et al. (6). The final dried sample was dissolved in 60 µl of 50% CH3CN,
25 mM H3PO4 (solvent A), and a
portion was injected onto a C18 reverse-phase HPLC column.
The column was eluted with a 4-ml linear gradient of solvent A to 100%
CH3CN, 25 mM H3PO4
(solvent B), followed by 1 ml of solvent B at a flow rate of 100 µl/min. Fractions of 100 µl were collected and their radioactivity
determined by scintillation counting. Trans,trans-farnesol
(FOH, Sigma) and all-trans-geranylgeraniol (GGOH, American
Radiolabeled Chemicals, Inc.) were used as elution standards.
RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-Subunit in
Vivo--
To identify PRL-2 interacting proteins, we performed a yeast
two-hybrid screen with full-length PRL-2 fused to the GAL4 DNA-binding domain as bait. The expression of the fusion protein in Y190 yeast cells was verified by immunoblotting (data not shown). A human HeLa
cell cDNA library fused to the GAL4 activating domain under the
control of the constitutive alcohol dehydrogenase 1 promoter was
transfected into Y190 cells that expressed DNA-binding domain-PRL-2. Ten million colonies were selected on medium lacking Trp, Leu, and His
and supplemented with 25 mM 3-amino-1,2,4-triazole. Among others, one colony was identified that showed growth on the selective medium and -galactosidase activity, indicative of an interaction between PRL-2 and a library protein in these cells. The plasmid was
isolated and sequenced. The insert was in-frame with the cDNA that
coded for the human GGT II -subunit.
-subunit of GGT II,
we used PRL-1 and PRL-3 as bait and co-transfected the yeast with a
plasmid expressing GAL4(DNA-binding domain)-GGT II. The expression
of the fusion proteins in Y190 yeast cells was verified by
immunoblotting (data not shown). Despite the high homology between
different PRL-PTP family members, only PRL-2 interacted with the GGT II
subunit in the yeast two-hybrid system (Fig.
1). As GGT II is a prenyltransferase, we
also tested the dependence of the interaction on the presence of the
C-terminal prenylation sequence, the CAAX box, of PRL-2. A
prenylation-deficient mutant of PRL-2 lacking the CAAX box,
PRL-2(cd), did not interact with GGT II (Fig. 1).
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Fig. 1.
Interaction of the GGT II -subunit with
PRL-2 in the yeast two-hybrid system. Yeast were co-transfected
with pGADGH-GGT II and pAS2-1 expressing the indicated PRL-PTPs.
Co-transfection with vectors expressing known interacting proteins
(CLONTECH) were used as a positive (+ve) control,
and the empty vector pAS2-1 was used as negative control.
GGT II in mammalian cells. HeLa cells were transiently co-transfected with Myc-tagged PRLs
and FLAG-tagged GGT II. Since GGT II is a soluble protein mainly
localized in the cytosol (10), non-detergent-extracted soluble
fractions from the HeLa cells were used to carry out anti-Myc and
anti-FLAG immunoprecipitations. Virtually all the expressed GGT II
was indeed present in this soluble cytosolic fraction (Fig.
2A, upper panel, compare
lanes 1-4 with lanes 5-8). More PRL-2 was
present in the cytosol than in the pellet (Fig. 2A, lower
panel, compare lanes 3 and 7), while about
one-third of the PRL-1 partitioned into the cytosol (Fig. 2A,
lower panel, compare lanes 2 and 6).
However, comparatively less of the total PRL-3 was found in the soluble
extracts (Fig. 2A, lower panel, compare lanes 4 and 8). PRL-2 and GGT II co-immunoprecipitated with one
another, as evidenced by the presence of FLAG-GGT II in Myc-PRL-2
immunoprecipitates (Fig. 2B, lane 6), and by the presence of Myc-PRL-2 in anti-FLAG immunoprecipitates (Fig. 2C, lane 6). No GGT II was detected in myc-PRL-1 immunoprecipitates and Myc-PRL-1 was not present in anti-FLAG immunoprecipitates (Fig. 2,
B and C, lane 5). Likewise, no association was
detected between PRL-3 and GGT II (Fig. 2, B and C,
lane 7). These results confirm the in vivo interaction
of PRL-2 and GGT II and demonstrate that this involves specific
features or properties of PRL-2.
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Fig. 2.
Specific association of PRL-2 with
GGT II in HeLa cells. HeLa cells were
transiently transfected with the FLAG-tagged GGT II and without
(mock) or with the Myc-tagged PRL-PTPs. A, distribution of
the expressed PRL-PTPs and GGT II between the cytosol and membrane
fractions. Cytosol fractions (Cytosol) and membrane
(Pellet) fractions were probed with anti-FLAG (upper
panels) or anti-Myc (bottom panels) antibodies.
B and C, association of PRL-PTPs with GGT II.
Cytosol fractions (Cytosol), anti-Myc immunoprecipitates
(IP myc), and anti-FLAG immunoprecipitates (IP
flag) were probed with anti-FLAG (upper panels) or
anti-Myc (bottom panels) antibodies.
-Subunit Are Associated in the Early
Endosome--
PRL-2 is localized in the early endosome compartment in
a prenylation-dependent manner (28). In transfected CHO
cells and NIH 3T3 cells, PRL-2 showed strong perinuclear staining and
weak plasma membrane staining visualized by immunofluorescence. A
prenylation-deficient PRL-2 mutant was redirected to the nucleus and a
farnesyltransferase inhibitor, FTI-277, caused the same nuclear
relocalization (28). We found essentially the same results in
transiently transfected HeLa cells, but with enhanced diffuse
cytoplasmic staining of expressed wild-type PRL-2 following treatment
with FTI-277, and of expressed PRL-2(cd) (Fig.
3). The readily apparent cytoplasmic staining may reflect a higher level of PRL-2 expression in transiently transfected HeLa cells compared to that in the stably transfected CHO
and NIH 3T3 cells. Together these results indicate that prenylation plays an important role in the subcellular localization of PRL-2.
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Fig. 3.
Farnesylation-dependent early
endosome localization of PRL-2. HeLa cells transiently expressing
Myc-tagged PRL-2 or PRL-2(cd) were treated without or with FTI-277 for
16 h and processed for immunofluorescence visualization of the
Myc-PRLs by fluorescein isothiocyanate-conjugated anti-Myc antibody.
Bar, 10 µm.
GGT II and Myc-tagged PRL-2 or
PRL-2(cd) mutant. As observed in previous experiments, the prenylated
and early endosome-localized wild-type PRL-2 and GGT II
co-immunoprecipitated with one another (Fig. 4A, lanes 4 and 7).
However, the non-prenylated PRL-2(cd) mutant failed to interact with
GGT II (Fig. 4A, lanes 5 and 8). The lack of
interaction cannot merely be due to physically separate pools of
cytoplasmic GGT II and nuclear PRL-2(cd), as some PRL-2(cd) is
present in the cell cytoplasm (Fig. 3) and likely represents the
soluble PRL-2(cd) protein that was extracted together with soluble
GGT II (Fig. 4A, lane 2). Likewise, in the yeast
two-hybrid system we observed that the prenylation deficient mutant
PRL-2(cd) did not interact with GGT II, despite these expressed
proteins being directed to the yeast nucleus (Fig. 1). Nevertheless,
wild-type PRL-2 did interact with GGT II in the yeast nucleus (Fig.
1). These results suggested that co-localization of PRL-2 and GGT II
is not sufficient for interaction, and that the early endosomal localization of PRL-2 per se is not required for the
physical association of PRL-2 and GGT II in vivo.
However, prenylation or the C-terminal prenylation sequence of PRL-2 is
necessary for interaction.
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Fig. 4.
Farnesylation-dependent
association of PRL-2 with GGT II. HeLa
cells were transiently transfected with FLAG-tagged GGT II and
without (mock) or with the Myc-tagged PRL-2 or PRL-2(cd).
The cytosol fraction (Cytosol), anti-FLAG immunoprecipitates
(IP flag), and anti-Myc immunoprecipitates (IP
myc) were probed with anti-FLAG (upper panels) or
anti-Myc (bottom panels) antibodies. A, failure
of a CAAX box-deficient mutant of PRL-2 (PRL-2(cd) to
interact with GGT II. B, farnesyltransferase inhibitor
FTI-277 prevents the interaction of PRL-2 with GGT II. The cells
were treated with 10 µM FTI-277 for 16 h
(lanes 2, 5, and 8) or left untreated
(lanes 1, 3, 4, 6, 7, and 9) prior to
harvest.
GGT II and prenylated PRL-2 or unprenylated
PRL-2 possessing the CAAX box. HeLa cells were transiently transfected with PRL-2 and GGT II in the presence or absence of the
farnesyltransferase inhibitor FTI-277 for 16 h prior to harvest.
Whole cell lysates were prepared and co-immunoprecipitations performed.
Once again, wild-type PRL-2 from FTI-277 untreated cells was observed
to interact with the GGT II -subunit as visualized by immunoblotting
(Fig. 4B, lanes 4 and 7). Upon treatment with FTI-277, the expression level of PRL-2 was virtually unchanged (Fig.
4B, lanes 1 and 2) but the association with the
GGT II -subunit was lost (Fig. 4B, lanes 5 and
8). This was consistent with the study of PRL-2(cd)
described above, and indicated that not only the CAAX box,
but modification of PRL-2 by prenylation was required for interaction.
As prenylated PRL-2 is in the early endosome and not in the cytoplasm
or in the nucleus, this is the subcellular pool of PRL-2 that can
interact with GGT II.
GGT II did not alter the prenylation status of
PRL-2 (data not shown). Thus the HPLC analysis showed that PRL-2 was
indeed modified by a farnesyl isoprenoid and that the modification
could be inhibited by a farnesyltransferase inhibitor, consistent with
our previous study (28). Furthermore, PRL-2 is not geranylgeranylated
in vivo.
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Fig. 5.
Analysis of the prenyl groups attached to
PRL-2 in vivo. A, mevalonate labeling
of PRL-2. HeLa cells expressing Myc-tagged PRL-2 were incubated with
[3H]mevalonolactone and 30 µM lovastatin
overnight. The cells were treated with 10 µM FTI-277 for
16 h (lanes 3 and 4) or left untreated
(lanes 1 and 2) prior to harvest. Cell lysates
(WCL) (lanes 1 and 3) were
immunoprecipitated with anti-Myc antibody (IP myc)
(lanes 2 and 4) and analyzed by SDS-PAGE and
fluorography. B and C, isoprenoid analysis of
PRL-2 from HeLa cells. The isoprenoids attached to PRL-2 in
B, the immunoprecipitate described in A, and in
C, immunoprecipitated PRL-2 from FTI-277-treated HeLa cells,
were determined by C18 reverse-phase HPLC following methyl
iodide cleavage. Elution times of the trans,trans-farnesol
(FOH) and all-trans-geranylgeraniol
(GGOH) standards are indicated by arrows.
GGT II. The CCVQ prenylation motif of PRL-2 was altered by
site-directed mutagenesis to CSVQ. This PRL-2 mutant has the same
prenylation motif as Drosophila PRL-1 (dPRL-1) (28,
34) and can only be the substrate of a CAAX
prenyltransferase. Whole cell lysates from HeLa cells transiently
expressing Myc-tagged wild-type PRL-2 or CSVQ mutant PRL-2 together
with FLAG-tagged GGT II were probed for the expression of both
proteins (Fig. 6, lane 1-3)
and immunoprecipitated with anti-Myc or anti-FLAG antibodies. Both the
wild-type PRL-2 (Fig. 6, lanes 4 and 7) and the
CSVQ mutant PRL-2 (Fig. 6, lane 5 and 8) co-
immunoprecipitated with GGT II. These results suggest that PRL-2 is
not a substrate for GGT II, and that their physical association occurs
after the completion of the farnesylation of PRL-2 and its consequent
proper subcellular localization.
View larger version (40K):
[in a new window]
Fig. 6.
Interaction of PRL-2(CSVQ) mutant with
GGT II. HeLa cells were transiently
transfected with FLAG-tagged GGT II and without (mock) or
with Myc-tagged PRL-2 or PRL-2(CSVQ). The cytosol fraction
(Cytosol), anti-FLAG immunoprecipitates (IP flag)
and anti-Myc immunoprecipitates (IP myc) were probed with
anti-FLAG (upper panels) or anti-Myc (bottom
panels) antibodies.
GGT II--
PRL-1 and PRL-3 are prenylated and present in the early
endosome (28), yet no interaction of these PRLs with GGT II was detected, suggesting an additional unique feature of PRL-2 is required.
To identify the region of PRL-2 involved in interaction with the GGT
II subunit, we generated a series of swap mutants (Fig.
7A) by replacing segments of
PRL-2 with the corresponding regions from its closest homologue, PRL-1.
HeLa cells were transiently transfected with wild-type Myc-tagged PRL-2
or PRL-1/-2 swap mutants (swap-1 to -5) together with FLAG-tagged
GGT II. Whole cell lysates were prepared and probed for Myc-tagged
protein (Fig. 7B, bottom panel) and FLAG-tagged protein
(Fig. 7B, top panel), demonstrating equivalent levels of
expression from the various transfections. Anti-Myc immunoprecipitates
were prepared from the lysates and probed for the presence of PRL-PTPs
or GGT II. Besides wild-type PRL-2 (Fig. 7B, lane 2),
swap-1 (Fig. 7B, lane 3), swap-3 (Fig. 7B, lane
5), and swap-5 (Fig. 7B, lane 7) associated with the GGT II -subunit. All of these proteins have in common the feature of
possessing at least the C-terminal half of PRL-2 (amino acids 93-167).
The PRL-1/-2 chimeric proteins possessing the C-terminal half of PRL-1
failed to interact with GGT II -subunit (Fig. 7B, lanes 4 and 6). Amino acid alignment of the C-terminal halves of
PRL-2 and PRL-1 revealed virtually identical sequences, with the
exception of a 3-amino acid insertion immediately preceeding the
CAAX box sequence of PRL-1 (27). Apart from this, there are
three conservative substitutions near the C terminus
(Lys161, Ser163, and Ile172 in
PRL-1 for Arg158, Thr160, and
Val166 in PRL-2, respectively), one near the N terminus of
this region (Ile100 in PRL-1 with Val97 of
PRL-2), and a non-conservative substitution of Gly122 in
PRL-1 with Cys119 in PRL-2. As PRL-3 also possesses the
same or similar amino acid differences with PRL-2, one or more of these
could account for the differential interaction of PRL-2 with GGT
II.
View larger version (30K):
[in a new window]
Fig. 7.
The C-terminal region of PRL-2 is required
for the interaction with GGT II.
A, schematic drawing of the PRL-1/-2 swap mutants. The amino
acids at the front and end of the regions from PRL-1 or PRL-2 in the
swap mutants are numbered. B, HeLa cells were transiently
transfected with FLAG-tagged GGT II and without (mock) or
with PRL-2 or the indicated PRL-1/-2 swap mutants. The cytosol
fractions (Cytosol) were probed with anti-Myc (bottom
panels) and anti-FLAG (upper panels) antibodies.
C, Anti-Myc immunoprecipitates (IP myc) were
probed with anti-FLAG (upper panels) and anti-Myc
(bottom panels) antibodies.
-Subunit Disrupts the Interaction of PRL-2 with
GGT II--
GGT II functions as an / heterodimer to prenylate
Rab proteins when they are bound to an escort protein termed REP (11, 35). To determine whether PRL-2 could bind to GGT II when the latter
was complexed with the GGT II -subunit (GGT II), we co-expressed and GGT II in the presence or absence of PRL-2 and examined protein associations. The HA-tagged GGT II was expressed as a ~68-kDa band (Fig. 8, lanes
2 and 3, upper panel), and was only detectable when
co-expressed with GGT II (data not shown) (36). In the absence of
PRL-2, GGT II complexed with GGT II as shown by reciprocal
immunoprecipitations and immunoblotting (Fig. 8, lanes 5 and
6, upper and middle panels). When PRL-2 was
expressed together with and GGT II, no PRL-2 was detectable in
the GGT II or the GGT II immunoprecipitates, although in both
cases the other GGT II subunit was present in the complex (Fig. 8,
lanes 8 and 9). Immunoblotting of these
immunoprecipitates detected faint reactive bands in the vicinity of
PRL-2, but these are the light chains of the immunoprecipitating
antibodies and not PRL-2, as evidenced by their presence in similar
immunoprecipitates of lysates in which PRL-2 was not expressed (Fig. 8,
lanes 5 and 6). Also, immunoprecipitation of
Myc-PRL-2 did not reveal any associated or GGT II (Fig. 8,
lane 7), although in the absence of GGT II expression,
GGT II consistently co-immunoprecipitated with PRL-2 (see previous
figures). These results indicate that the binding of GGT II and
PRL-2 to GGT II may be mutually exclusive.
View larger version (57K):
[in a new window]
Fig. 8.
GGT II can disrupt the
interaction of PRL-2 with GGT II. HeLa
cells were transiently transfected with myc-PRL-2, HA-GGT II, and
FLAG-GGT II as indicated. The cytosol fraction (Cytosol)
was used to prepare anti-HA (IP HA), anti-FLAG (IP
flag), and anti-Myc (IP myc) immunoprecipitates, which
were probed with anti-HA (upper panels), anti-FLAG
(middle panels), or anti-Myc (bottom panels)
antibodies.
GGT II complex and effect
reduction of the / GGT II complex, with a consequent reduction of
endogenous GGT II activity. To test this, the GGT II activity of
lysates of HeLa cells expressing or not expressing Myc-tagged PRL-2 was
assayed in vitro by measuring the geranylgeranylation of
added Rab3a, a GGT II substrate. PRL-2 expression resulted in lower GGT
II activity toward Rab3a (Fig.
9A). The results of several
experiments showed a significant overall 33% (±11) reduction in GGT
II activity (Fig. 9B). Considering that the efficiency of
PRL-2 transfection is about 40% (as assessed by indirect
immunofluorescent visualization of Myc-PRL-2 with anti-Myc antibody and
an fluorescein isothiocyanate-labeled second antibody), this supports
the idea that PRL-2 can act as an inhibitor of GGT II, and that the
mechanism of inhibition involves displacement of the GGT II
subunit.
View larger version (27K):
[in a new window]
Fig. 9.
Effect of PRL-2 expression on GGT II
activity. A, lysates of HeLa cells transiently
transfected with empty vector or vector expressing Myc-tagged PRL-2
were incubated with [3H]GGPP and with or without Rab3a
protein as described under "Experimental Procedures." The
geranylgeranylated Rab3a protein is indicated by the arrow.
B, the Rab3a labeling in three independent experiments was
quantified by densitometry. The bars represent the mean ± S.D. (p < 0.005). C, lysate loading
control for the GGT II assay. HeLa cell lysates were probed with
anti-actin (upper panel) or anti-Myc (bottom
panel) antibodies.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
GGT II
in vivo (Figs. 1 and 2). The association of PRL-2 with
GGT II depends on PRL-2 prenylation, as a potent farnesyltransferase inhibitor, FTI-277 (33), can abolish the association (Fig.
4B). Moreover, the C-terminal prenylation motif deletion
mutant PRL-2(cd) fails to interact with GGT II in vivo
(Figs. 1 and 4A). The association is not substrate-like,
because HPLC analysis demonstrates that PRL-2 is modified by a farnesyl
isoprenoid and this modification is inhibited by a FT inhibitor (Fig.
5). Additionally, a farnesylation-only mutant of PRL-2, PRL-2(CSVQ), is
not impaired in its ability to interact with GGT II, clearly showing
that geranylgeranylation of PRL-2 is not required. In a previous study
we showed that all the PRLs can be prenylated in vitro, and
that in vivo prenylation is key to their plasma membrane and
early endosome localization (28). Taken together with the present
results, it appears likely that PRL-2 and GGT II are preferentially
associated in the early endosome.
subunit contains
most of the residues in the active site (37). However, GGT II is
active only when complexed to GGT II (36). We have demonstrated that
PRL-2 associates with GGT II, but that the presence of GGT II and
formation of the / heterodimer excludes PRL-2 binding. This is
the situation when all three proteins are heterologously expressed and
present in the cell in high amounts. If only PRL-2 is transiently
expressed, an inhibition of cellular GGT II activity is observed,
suggesting that the higher amount of PRL-2 relative to endogenous
GGT II can inhibit GGT II binding to GGT II. We propose that
PRL-2 and GGT II bind to GGT II in a mutually exclusive manner,
and that regulation of the relative amounts of PRL-2 and GGT II can
modulate GGT II activity. This could be accomplished by the regulation
of PRL-2 or GGT II gene expression, or by translocation of PRL-2 to
the nucleus where, as we have shown, GGT II is inaccessible for
PRL-2 binding. The key factor in determining PRL-2 subcellular
localization is its farnesylation (28), and this can potentially be
enhanced by environmental conditions which increase isoprenoid
synthesis such as stress (heat shock, UV radiation, and arsenite) or
heat and light (38-40). In this way, farnesylation of PRL-2 would be
stimulated and act to inhibit GGT II activity and Rab
geranylgeranylation, suggesting a cellular mechanism by which the
activities of the different prenyltransferases may be reciprocally balanced.
/ GGT II heterodimer for GGT
II activity, it is intriguing that while GGT II is widely expressed,
GGT II expression appears to be negligible in certain tissues such
as lung, kidney, and in particular, muscle (36). PRL-2 is highly
expressed in these GGT II-deficient tissues, particularly in muscle
(27), and in such situations farnesylated PRL-2 may be the predominant
GGT II binding partner. Treatment with FT inhibitors would result in
nuclear localization of PRL-2, and might thus be especially effective
in increasing Rab geranylgeranylation in these tissues.
GGT II (Figs.
1 and 2), suggesting that some element other than prenylation may play
an important role in association. In the swap test for GGT II
binding, only the chimeric PRL proteins possessing an intact PRL-2
C-terminal sequence can interact with GGT II (Fig. 7). Apart from a
few mainly conservative amino acid substitutions, a 3-residue insertion
just before the CAAX boxes of PRL-1 and -3 is the most
divergent feature between these PRLs and PRL-2. Possibly this region of
PRL-2 is directly involved in the interaction with GGT II, as with some
GGT II Rab substrates where the least conserved C-terminal 25 amino
acids, or hypervariable region, influences their direct interaction
with GGT II (41). Alternatively, this region may indirectly provide
specificity by directing the various PRLs to different subcellular
locations or microlocations such that only PRL-2 is appropriately
positioned to interact with GGT II. The 3-residue
pre-CAAX box insert is distinct even between PRL-3 and
PRL-1, and thus could account for different subcellular localizations/functions among all the PRLs. It has been proposed that
divergent C-terminal sequences of small GTPases dictate their specific
association with membrane structures. Studies of Ras proteins have
revealed that the trafficking of Ras to the plasma membrane is largely
dependent on a second signal (besides farnesylation) within the
hypervariable region (42, 43). Different isoforms of Ras may be
targeted to specific subregions of the plasma membrane on the basis of
this second membrane localization signal (44, 45). In stably
transfected Chinese hamster ovary and NIH 3T3 cells, we have observed
that PRL-2 is enriched in perinuclear regions and its staining at the
plasma membrane is much less obvious compared with that of PRL-1 and
-3. Transferrin receptor/PRL co-internalization experiments suggest
that PRL-2 may reside in the later recycling subcompartment of the
early endosome, while large amounts of PRL-1 and -3 reside in the
plasma membrane and early
subcompartment.2 Whether the
C-terminal amino acid variation between the PRLs differentially
determines their precise membrane destination is unknown, but could
explain their localization and perhaps the GGT II binding differences.
ACKNOWLEDGEMENTS
GGT II
cDNA, and D. Kesuma and B. Qi for assistance with HPLC isoprenoid analysis.
FOOTNOTES
To whom correspondence should be addressed: Institute of Molecular
and Cell Biology, 30 Medical Dr., Singapore 117609, Republic of
Singapore. Tel.: 65-874-3742; Fax: 65-779-1117; E-mail:
mcbcp@imcb.nus.edu.sg.
ABBREVIATIONS
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INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
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