From The Diabetes Unit and Medical Services and the Department of Medicine, Harvard Medical School, Massachusetts General Hospital East, Charlestown, Massachusetts 02129
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ABSTRACT |
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The small GTP-binding protein Ras is pivotal in transmitting growth and differentiation signals downstream of cell surface receptors. Many observations have indicated that Ras transmits signals from cell surface receptors into multiple pathways via direct interaction with different effectors in mammalian cells. We have identified a novel potential Ras effector or target named Nore1. Nore1 has no significant sequence similarity to known mammalian proteins and lacks an identifiable catalytic domain, but contains sequence motifs that predict DAG_PE binding and SH3 domain binding. We show that Nore1 directly interacts with Ras in vitro in a GTP-dependent manner, and the interaction requires an intact Ras effector domain. Nore1 becomes associated with Ras in situ following activation of epidermal growth factor receptor in COS-7 and in KB cells.
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INTRODUCTION |
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The small GTP-binding protein Ras (Ha-, Ki-, and N-Ras) plays a central role in transmitting proliferative and differentiation signals downstream of cell surface receptors in mammalian cells. Ras has been demonstrated to relay signals from receptor tyrosine kinases (1), (e.g. EGF1 receptor), non-tyrosine kinase receptors (2) (e.g. T cell antigen receptor), and heterotrimeric G protein-coupled receptors (3). The understanding of the biochemical mechanism by which Ras transmits signals in higher eucaryotic cells has been greatly clarified in recent years. Ras is located at the inner surface of the plasma membrane; activation of cell surface receptors promotes the exchange of Ras-GDP for GTP, thereby converting Ras to the active state. This activation results from GTP-induced conformational change, wherein two discrete Ras segments, called switch I (or the effector domain loop aa 32-40) and switch II (aa 60-72) exhibit a significant displacement as compared with the GDP-bound state. This conformational change renders Ras able to interact effectively with its downstream effectors or targets (4). The first Ras effectors in mammalian cells to be identified are the protein kinases of the Raf family. GTP-bound Ras directly binds Raf primarily through an interaction between the switch I region and amino-terminal segment on Raf (amino acids 50-150). The ability of Raf to bind to Ras in a GTP-dependent manner, in vitro and in situ, is the cardinal biochemical evidence in support of Raf's role as a direct effector of Ras (5). The Raf-MEK-Erk pathway is the best characterized Ras effector pathway and is required for transformation of rodent fibroblasts by oncogenic Ras (6). However, In recent years, many observations have indicated that Ras transmits signals into multiple effector pathways. For instance, constitutively active Ras and Raf both transform NIH3T3 fibroblasts, but only constitutively active Ras, but not Raf, can transform rat intestinal epithelial cells (RIE-1), thus pathways besides the Raf-MEK-Erk pathway need to be activated to transform RIE-1 cells (7). Similarly, in PC-12 cells, activated Raf induces the expression of only a subset of genes which can be induced by oncogenic Ras or nerve growth factor (8). An elegant study demonstrated that in Hela cells and NIH3T3 fibroblasts, the increase in Ras-GTP charging achieved immediately after release from mitosis is much less than a second phase of Ras activation that occurred some 5 h later, in mid-G1. Interestingly, only the first phase of Ras activation was accompanied by Erk activation, whereas the latter, much stronger Ras activation occurred without significant Erk activation (9). The biologic significance of Ras activation in mid-G1 phase, and the nature of the effectors recruited by activated Ras at that time is entirely unknown.
Following on the discovery of Raf as the initial Ras effector in higher
eucaryotic cells, a number of candidate Ras effectors have been
proposed based on the ability of these polypeptides to bind to Ras
through its effector loop, and in a GTP-dependent fashion,
including PI 3-kinase, members of the Ral-GDS family, Rin 1, AF-6,
diacylglycerol kinases, PKC-, MEKK1, etc. The standing of these
polypeptides as candidate Ras effectors has been reviewed (10, 11). We
used the yeast two-hybrid system to look for novel proteins that
directly interact with Ras. We describe here the identification of a
potential new Ras effector, which we have named Nore1.
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EXPERIMENTAL PROCEDURES |
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Two-hybrid Screen--
A cDNA encoding V12-Ha-Ras deleted of
the last four amino acids was subcloned into vector pAS-CYH-II
carboxyl-termianl to the Gal-4 DNA binding domain to form the bait
construct pAS-Ras. 100 µg of cDNA made from a mouse T cell
library constructed in the GAL-4 DNA activation domain vector pACT was
transformed into the yeasts expressing pAS-Ras, and the transformants
were plated out on HisLeu
Trp
selection plates. After 8 days, 20 large colonies appeared. X-gal filter assay was performed for all the colonies and all showed strong
blue color.
cDNA Cloning of Nore1--
The 2.5-kb cDNA encoding
Nore1 from the initial two-hybrid screen was labeled with
[-32P]dCTP and used to screen a cDNA library made
from mouse brain (CLONTECH's mouse brain
5'-stretch plus cDNA library in
-gt 10 vector, catalog number ML
3000a). A positive clone, which contains a 3-kb insert, was
isolated.
Tissue and Cell Line Western Blot-- Sprague-Dawley rats (65 g) were starved overnight, anesthetized with pentobarbital, and tissues were excised in the following order: gastrocnemius, testis, spleen, kidney, liver, lung, and heart. Brain was excised from other intact anesthetized animals after decapitation. Cell lines were gown to 80-90% confluence before harvesting. Both tissues and cell lines were disrupted and extracted in radioimmune precipitation buffer.
Detection of Ras/Nore1 Binding in Vitro--
Purified,
procaryotic recombinant c-Ha-Ras (2.5 mg/ml) was loaded with GTPS (2 mM) or GDP
S (2 mM) at 37 °C for 15 min in the buffer containing 50 mM Tris-HCl, pH 7.5, 7.5 mM EDTA, 2.5 mM MgCl2 0.5 mg/ml
bovine serum albumin, 1 mM dithiothreitol. Various amounts
of GTP
S- or GDP
S-loaded Ras proteins were mixed with purified
procaryotic recombinant GST-Nore1-(188-413). Subsequent steps were
essentially the same as described previously (12)
Detection of Ras-Nore1 Association in COS-7 Transient Expression
System--
COS-7 cells were plated at a density of 1.2 million/10-cm
dish and transfected 24 h later with 7 µg of pMT2-HA-c-Ha-Ras or empty vector and 12 µg of pEBG-GST-Nore1 using the DEAE-dextran method. 48 h later, cells were starved for 24 h and
subsequently were stimulated with 100 ng/ml EGF for various times.
Cells were extracted in lysis buffer (30 mM HEPES, pH 7.4, 1% Triton X-100, 20 mM -glycerophosphate, 2 mM NaPPi, 1 mM orthovanadate, 20 mM NaF, 20 mM KCl, 2 mM EGTA, 3 mM EDTA, 7.5 mM MgCl2, 14 mM
-mercaptoethanol, and a mixture of protease
inhibitors). Lysates were freeze-thawed once and spun at 17,000 × g for 20 min. Supernatants were incubated with anti-HA
antibodies and protein A-G-Sepharose beads for 3-4 h at 4 °C and
then washed extensively with lysis buffer. The washed beads were eluted
in SDS sample buffer and the extracted proteins subjected to SDS-PAGE,
transferred on PVDF membranes, and probed using the antibodies
indicated. Bound antibodies were visualized using ECL.
Detection of Ras-Nore1 Association in KB Cells-- KB cells were grown to 80% confluence, starved of serum for 24 h, and subsequently stimulated with EGF (100 ng/ml) for various time. Lysates were prepared as for the COS-7 cells, and Ras was immunoprecipitated with anti-Ras antibody (Y13-238) and protein A-G-Sepharose beads. Subsequent steps were similar to those used in the COS-7 experiment.
Antibody Production-- GST-Nore1-(188-413) was used to immunize New Zealand White rabbits. The antiserum was first depleted of GST-reacting antibodies by repeated incubation with immobilized GST. The GST-depleted antiserum was then affinity-purified using immobilized Nore1-(188-413) on a PVDF membrane.
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RESULTS AND DISCUSSION |
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A yeast two-hybrid screen was carried out to identify potential
new Ras effectors in mammalian cells. One million yeast transformants coexpressing a V12 Ras bait plasmid and a cDNA library prepared from activated mouse T cells were screened. Twenty strong positives were obtained, which showed both interaction-dependent
growth on selective media and interaction-dependent
expression of Lac-Z activity. DNA sequencing revealed that 18 of the 20 positives were either mouse A-Raf or c-Raf-1. Two positive clones both
encoded a 2.5-kb cDNA representing a new gene, which was named
Nore1 (novel Ras effector).
Although the sequence indicated that an incomplete open reading frame
had been recovered, we made use of the yeast two-hybrid system to
examine the specificity of the interaction of Nore1 with two
Ras-related proteins Rap1b and RalA, and two well defined Ras effector
domain mutants, Ras 12V34,38A or Ras 12V38N, which are defective in
binding known Ras effectors like Raf (12). Rap1b and RalA belong to the
Ras subfamily of small GTP-binding proteins (13); Rap1 (A and B) has
identical sequence to Ras in the region corresponding to the Ras
effector domain (aa 32-40) and binds to several previously identified
Ras effectors like Raf, PI 3-kinase and Ral-GDS, whereas RalA does not
bind to these polypeptides. Nore1 interacts with wild type Ras but not
with Ras 12V
34,38A and Ras 12V38N. Nore1 also interact with Rap1b,
but not with RalA (Table I). Thus, the
interactions of Nore1 with these Ras-related proteins parallels closely
the pattern exhibited by other well established Ras effectors.
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The 2.5-kb Nore1 cDNA insert was used as the hybridization probe to isolate the entire cDNA from a mouse brain cDNA library. A 3018-base pair cDNA was isolated. The cDNA sequence around the first ATG matches the Kozak consensus sequence for a translational start. The open reading frame from this methionine includes 413 amino acids, as shown in Fig. 1A, yielding a highly basic polypeptide (pI = 9.41) with a predicted molecular mass of 46.4 kDa. One obvious structural feature of Nore1 is the presence of a cysteine-histidine-rich segment typical of a diacylglycerol/phorbol ester (DAG_PE) binding site (14) (aa 118-165, H-X13-C-X2-C-X10-C-X2-C-X4-H-X2-C-X7-C). Nore1 also has a proline-rich region in its amino-terminal region, with five PXXP sequences (aa 17-20, PEPP; aa 31-34. PPPP; aa 34-37, PARP; aa 77-80, PVRP; and aa 105-108, PQDP), which are possible SH3 domain binding sites (15). A search of the GeneBankTM using BLASTP command found that a Caenorhabditis elegans gene product called T24F1.3 has significant homology to Nore1. Fig. 1B shows the sequence similarity; the most significant homology between the two proteins is in their carboxyl-terminal regions. T24F1.3 has been suggested previously to contain a Ras/Rap association domain (RA domain) (16), located at aa 396-496. This domain is within the region most closely related in sequence to Nore1.
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Nore1 mRNA abundance and complexity in murine tissues was examined by Northern blot (Fig. 2A). A single mRNA generally about 3.1 kb was detected in most mouse tissues, although some size variation is noted. The highest levels are observed in brain, liver, and spleen, with barely detectable levels in heart.
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A polyclonal antibody was raised against a carboxyl-terminal fragment of Nore1 (aa 188-413) and purified by affinity chromatography using the recombinant antigen. Immunoblot of extracts prepared from different rat tissue is shown in Fig. 2B. A single immunoreactive band at 46 kDa is seen in a brain extract, which is in agreement with the predicted size of the polypeptide encoded by Nore1 cDNA isolated from the mouse brain library. A similar 46-kDa band is also seen in other tissues, including lung and testis. In addition, however, prominent immunoreactive bands at other molecular masses are seen in most tissues, and some tissues lack a 46-kDa band entirely (e.g. skeletal muscle, heart, spleen, and liver). All tissues but brain show a major 65-kDa band, and two bands around 55 kDa are also seen in lung, spleen, testis, and liver. The 65- and 55-kDa bands may represent isoforms of Nore1, the existence of which is suggested by the partial cDNAs isolated from a variety of cDNA libraries (data not shown). Alternatively, these bands may reflect polypeptides unrelated to Nore1, except for the presence of sequence epitopes recognized by the polyclonal antibodies to Nore1. The anti-Nore1 antibody also immunoblotted a single polypeptide in an extract prepared from C. elegans. This band is approximately 74 kDa, as compared with the molecular mass of T24F1.3 gene product of 69.1 kDa. The murine brain Nore1 cDNA was tagged at the Nore1 amino terminus with an HA epitope and expressed transiently in COS cells. As seen in Fig. 2C. HA-Nore1 shows the expected size of 46 kDa by immunoblot with anti-Nore1 antibodies. Extracts prepared from several cell lines were subjected to Nore1 immunoblot; of the cell lines examined, only BC3H1, a vascular smooth muscle-like line derived from a radiation-induced murine brain tumor, shows a single band at 46 kDa. A band of similar size is seen in several other cell lines, including RIE-1 (rat intestinal epithelial), MCF-7 (human breast cancer), HEK 293 (human embryonic kidney), and KB (human oral carcinoma); however, immunoreactive polypeptides of 55 kDa (RIE-1, MCF-7, HEK 293, and KB) and 65 kDa (RIE-1, HEK 293, and KB), are as or more abundant in these cell lines, and some lines show only bands other than the 46-kDa polypeptide (e.g. Huh-7, 40 kDa; L6, 55 kDa). We preabsorbed the affinity-purified anti-Nore1 antibodies with an excess amount of recombinant Nore1-(188-413) for 1 h and used this preabsorbed antibodies to probe the blots used in Fig. 2, B and C, and we did not see the predominant bands at 46, 55, and 66 kDa, suggesting that these bands in both figures are probably specific.
A GST-Nore1-(188-413) fusion protein (corresponding to the Nore1
polypeptide encoded in the initial cDNA isolate) was expressed and
purified from Escherichia coli. Procaryotic recombinant
c-Ha-Ras was loaded with GTPS or GDP
S, and various amounts were
mixed with a fixed amount of GST-Nore1-(188-413) or GST as control. After incubation at 30 °C for 20 min, GST or GST fusion proteins and
any associated proteins were recovered by addition of
glutathione-Sepharose beads. The beads were washed and eluted into SDS
sample buffer; proteins were separated by SDS-PAGE, transferred to PVDF
membrane, and probed for Ras using a monoclonal anti-Ras antibody. GST
-Nore1-(188-413), but not GST binds Ras, and considerably more
Ras-GTP
S is bound than Ras-GDP-
-S (Fig.
3). These results establish that the
effector loop-dependent interaction between Nore1 and Ras
identified by two-hybrid techniques reflects the direct binding of the
two proteins and that the binding between Nore1 and Ras is
GTP-dependent.
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We then attempted to detect an interaction between Nore1 and Ras in mammalian cells and to determine whether this binding was dependent on Ras activation in situ. COS-7 cells were cotransfected with plasmids encoding GST-Nore1 and HA-tagged c-Ha-Ras. Forty-eight hours later, cells were serum-starved for 24 h and then stimulated with EGF or TPA for various times, extracted into buffer containing Triton X-100, and HA-Ras was recovered using the anti-HA monoclonal antibody, 12CA5. The washed immunoprecipitates were eluted into SDS sample buffer and separated by SDS-PAGE, transferred to PVDF membrane, and probed with affinity-purified anti-GST polyclonal antibodies. As seen in Fig. 4A, GST-Nore1 was specifically pulled down with HA-c-Ha-Ras, but only after the cells were treated with EGF or TPA; the expression of HA-c-Ha-Ras and of GST-Nore1 was uniform throughout. Thus, Nore1 is not detectably associated with Ras in serum-starved COS cells; however, within 5 min after stimulation by EGF (or TPA), Nore1 associates specifically with Ras; this association diminishes by 15 min after EGF addition and is largely reversed by 40 min, probably reflecting the down-regulation of Ras activation after EGF treatment.
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We next attempted to detect an in situ association between endogenous Ras and endogenous Nore1, under conditions where the levels of the two polypeptides are not increased artificially by transient overexpression. We chose to examine the human oral carcinoma cell line KB, because Nore1 expression is readily detectable, and these cells express substantial numbers of EGF receptors. KB cells grown to 80% confluence were serum-starved for 24 h and then treated with EGF for various times. Triton X-100-soluble cell lysates were subjected to immunoprecipitation using the monoclonal anti-Ras antibody, Y13-238, which are known to enable isolation of Ras-Raf complexes. The Ras immunoprecipitates were washed extensively with the lysis buffer, eluted into SDS sample buffer and subjected to SDS-PAGE, transferred to PVDF membrane, and immunobloted with the affinity-purified polyclonal anti-Nore1 antibodies. As shown in Fig. 4B, although equal amounts of endogenous Ras were recovered in all samples, the Ras immunoprecipitates contain immunoreactive Nore1 only after treatment of the cells with EGF. The time course of Ras-Nore1 association after EGF treatment in KB cells is more sustained than that observed in COS-7 cells. This may reflect different time course of down-regulation of Ras activation in those cells. Interestingly, only the 46-kDa (and not the equally abundant 55-kDa) immunoreactive Nore1 polypeptide is recovered with c-Ras.
In summary, we have identified Nore1, a potential new Ras effector or
target, using the yeast two-hybrid screen with Ras as bait. We show
that Nore1 can bind Ras directly in vitro using purified
recombinant Ras and Nore1 polypeptides. The Ras/Nore1 association
in vitro depends strongly on Ras being in the GTP-bound form. We show that with yeast two-hybrid assay, Nore1 interacts with
Ras 12V but not two transformation defective effector loop mutants, Ras
12V34,38A and Ras 12V38N. This profile of interaction with Ras is
identical to that exhibited by known and potential Ras effectors,
including Raf, PI 3-kinase, Ral GDS, Rin1, and AF-6. We also show that
the Ras/Nore1 association occurs in vivo following EGF and
TPA activation of Ras in COS-7 cells overexpressing Ras and Nore1.
Finally, it is clear that a stimulus-dependent association
of endogenous Ras and Nore1 occurs following EGF receptor activation in
KB cells. To our knowledge, Nore1 is the only other candidate mammalian
Ras effector, other than Raf, wherein the endogenous polypeptide has
been demonstrated to associate with Ras in vivo following
receptor activation. Taken together, these properties indicate that
Nore1 is very likely to be a physiologic Ras effector.
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FOOTNOTES |
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* This work was supported in part by National Institutes of Health Grants GM51281 (to X.-F. Z.) and DAMD 17-94-54404 (to J. A.) and by a grant from Lilly Inc. (to J. A.) and ONASSIS (to D. V.).The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
To whom correspondence should be addressed. Tel.: 617-726-9450;
Fax: 617-726-9452; E-mail: zhang{at}helix.mgh.harvard.edu.
1
The abbreviations used are: EGF, epidermal
growth factor; aa, amino acid(s); PI, phosphatidlyinositol; X-gal,
5-bromo-4-chloro-3-indolyl -D-galactopyranoside; kb,
kilobase pair(s); GTP
S, guanosine 5'-O-(thiotriphosphate); GDP
S, guanyl-5'-yl
thiophosphate; GST, glutathione S-transferase; PAGE,
polyacrylamide gel electrophoresis; PVDF, polyvinylidene difluoride;
HA, hemagglutinin; TPA,
12-O-tetradecanoylphorbol-13-acetate; DAG,
diacylglycerol.
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REFERENCES |
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