(Received for publication, April 14, 1997, and in revised form, June 4, 1997)
From the Department of Molecular Genetics, University of Texas Southwestern Medical Center, Dallas, Texas 75235
SREBP cleavage-activating protein (SCAP) stimulates the proteolytic cleavage of membrane-bound SREBPs, thereby initiating the release of NH2-terminal fragments from cell membranes. The liberated fragments enter the nucleus and stimulate transcription of genes involved in synthesis and uptake of cholesterol and fatty acids. Sterols repress cleavage of SREBPs, apparently by interacting with the membrane attachment domain of SCAP. In the present studies we show that SCAP, like the SREBPs, is located in membranes of the endoplasmic reticulum and nuclear envelope. The COOH-terminal domain of SCAP, like that of the SREBPs, is located on the cytosolic face of the membranes. Co-immunoprecipitation experiments show that SCAP and SREBP-2 form a complex that can be precipitated with antibodies to either component. Complex formation occurs when cells express only the COOH-terminal domain of either SREBP-2 or SCAP, indicating that the complex forms between the two COOH-terminal domains. Truncation of SREBP-2 at its COOH terminus prevents the formation of complexes with SCAP and simultaneously reduces proteolytic cleavage. We conclude that proteolytic cleavage of SREBPs requires the formation of a complex with the COOH-terminal domain of SCAP and that SCAP is therefore a required element in the regulation of sterol and fatty acid metabolism in animal cells.
Sterol regulatory element-binding proteins (SREBPs)1 are membrane-bound transcription factors that regulate the synthesis and uptake of cholesterol and fatty acids in animal cells (reviewed in Ref. 1). Two SREBPs, designated SREBP-1a and SREBP-2, predominate in cultured cells. The activities of both SREBPs are regulated by the sterol content of the cells. When cells are replete with sterols, the SREBPs remain bound to membranes of the endoplasmic reticulum (ER) and nuclear envelope and are therefore inactive. When cells are depleted of sterols, a proteolytic process releases the active portions of the SREBPs, which enter the nucleus and stimulate transcription of genes in three pathways of lipid metabolism: 1) cholesterol biosynthesis (HMG-CoA synthase, HMG-CoA reductase, farnesyl diphosphate synthase, and squalene synthase) (1-4); 2) uptake of cholesterol and fatty acids from plasma (low density lipoprotein receptor and lipoprotein lipase) (1, 5); and 3) fatty acid biosynthesis (acetyl-CoA carboxylase, fatty acid synthase, and stearoyl-CoA desaturase-1) (1, 5-7).
The mechanism by which sterols control the proteolytic release of SREBPs from cell membranes is beginning to be elucidated through studies of cultured animal cells (1). These studies revealed that the SREBPs are tripartite proteins of ~1150 amino acids that are attached to membranes in a hairpin fashion (8, 9). The NH2-terminal segment of ~480 amino acids, which faces the cytoplasm, is a classic transcription factor of the basic-helix-loop-helix-leucine zipper family. This segment is followed by a hairpin-like membrane attachment domain that consists of two membrane-spanning sequences separated by a hydrophilic loop of ~30 amino acids that projects into the lumen of the ER or nuclear envelope. This is followed by a COOH-terminal segment of ~590 amino acids that projects into the cytoplasm.
In sterol-depleted cells, a protease clips each SREBP at Site-1, which is a Leu-Ser bond in the middle of the lumenal loop (9, 10). This breaks the covalent bond between the two membrane-spanning segments and allows a second protease to cleave at Site-2, which appears to be in the middle of the first transmembrane segment (10). Cleavage at Site-2 releases the NH2-terminal segment, which leaves the membrane, apparently with a portion of the membrane-spanning region still attached. The NH2-terminal segment then enters the nucleus, where it binds to sterol regulatory elements in the enhancers of the genes described above, thereby stimulating transcription (1). When cells are overloaded with sterols, proteolysis at Site-1 is abolished. Cleavage at Site-2 also declines since this cleavage requires prior cutting at Site-1 (9, 10). As a result, the NH2-terminal segments remain bound to membranes, and transcription of the lipid-related genes is diminished.
The biochemical identities of the proteases that cut at Sites-1 and -2 are unknown, but certain requirements for substrate recognition have been elucidated. The Site-1 enzyme requires an arginine that is three residues to the NH2-terminal side of the cleaved Leu-Ser bond (9, 10). (In hamster and human SREBP-2, this sequence is RSVLS) (11, 12). Even though it cuts on the lumenal side of the membrane, the Site-1 enzyme requires the cytoplasmic COOH-terminal domain of the SREBP. When this domain in SREBP-2 is shortened through truncation mutations, cleavage by the Site-1 protease is abolished.2 The Site-2 enzyme requires the sequence DRSR, which is immediately external to the first transmembrane domain (10).
Recently, our laboratory described a new protein designated SREBP cleavage-activating protein (SCAP) that appears to mediate sterol regulation of cleavage at Site-1 (13). A cDNA encoding a sterol-resistant mutant form of SCAP was isolated by expression cloning from a line of CHO cells with a dominant defect in sterol regulation. In these cells sterols cannot suppress cleavage of SREBPs at Site-1, and thus the cells overproduce cholesterol. Expression cloning traced this defect to a substitution of asparagine for aspartic acid at residue 443 of SCAP. When a cDNA encoding the D443N mutant of SCAP is transfected into normal cells, the cells show increased cleavage of SREBPs at Site-1, and sterols no longer down-regulate this cleavage. Overexpression of a cDNA encoding wild-type SCAP can exert a similar effect, but the D443N mutant is at least 10-fold more potent (13). We concluded from these data that SCAP normally stimulates cleavage at Site-1 and that its activity is abolished by sterols. The mutant SCAP is both superactive and resistant to inhibition by sterols.
The hypothesis regarding the function of SCAP is supported by an
analysis of the sequence of the 1276-amino acid protein, which reveals
that SCAP is divided into two domains. The NH2-terminal domain of ~730 amino acids consists of alternating hydrophobic and
hydrophilic segments that are compatible with approximately eight
membrane-spanning domains (13). This is followed by a COOH-terminal
domain of ~546 amino acids that is more hydrophilic and contains four
or five WD repeats of ~40 amino acids each. WD repeats are found in
more than 30 intracellular proteins of diverse function, including the
subunits of heterotrimeric G proteins (14). The latter proteins
contain seven WD repeats that are clustered together to form a
seven-bladed propeller-like structure, the blades of which mediate
contacts between the
subunit and the closely associated
and
subunits of the trimer (15, 16). Indeed, WD repeats are postulated, in
general, to mediate protein-protein interactions.
The striking feature of SCAP is the resemblance of its membrane domain to the membrane domain of HMG-CoA reductase, an ER enzyme involved in cholesterol synthesis (13). Like SCAP, HMG-CoA reductase is divided into two portions (17). The NH2-terminal half of the protein contains eight membrane-spanning regions (18). The COOH-terminal half of the protein, which projects into the cytoplasm, contains the entire catalytic domain of the enzyme (17). The membrane domain is responsible for sterol-regulated degradation of the enzyme (19, 20). In sterol-depleted CHO cells, the enzyme has a long half-life of greater than 10 h. When sterols are added, the enzyme is destroyed with a half-life of 1.5 h (19). Rapid degradation requires the membrane domain of the enzyme, which has been postulated to have a sterol-sensing function (19).
The membrane domain of SCAP contains a region (postulated membrane-spanning segments 2-6) that shows 25% sequence identity and 55% similarity to the corresponding portion of the sterol-sensing region of HMG-CoA reductase. This region includes aspartic acid 443, which is the site of the activating mutation in SCAP (although this residue is a valine in HMG-CoA reductase) (13). These similarities led us to postulate that the membrane domain of SCAP, like that of HMG-CoA reductase, is a sterol sensor. There is no evidence that sterols accelerate the degradation of SCAP, as they do of HMG-CoA reductase. Instead, sterols may interact with the membrane domain of SCAP so as to regulate its ability to stimulate the cleavage of SREBPs at Site-1 (1).
In the current studies we have sought to further understand the mechanism by which SCAP may regulate the cleavage of SREBPs. Through use of a co-immunoprecipitation assay, we show that the COOH-terminal cytoplasmic domain of SREBP-2 forms a complex with the COOH-terminal WD repeat domain of SCAP. We postulate that this interaction allows SCAP to recruit a protease that cleaves SREBPs at Site-1. This hypothesis would explain the finding that cleavage at Site-1 requires the COOH-terminal domain of SREBPs.
We obtained monoclonal antibodies IgG-HSV-TagTM and IgG-T7-TagTM from Novagen; v-Ha-Ras(Ab-1)-agarose-linked monoclonal antibody from Oncogene; affinity-purified donkey anti-mouse and anti-rabbit IgG from Jackson Immunoresearch Laboratories; and Protein G-Sepharose® 4 Fast Flow beads from Pharmacia Biotech Inc. Other reagents were obtained from sources as described previously (8, 21).
Constructions of PlasmidspTK-HSV-Ras-BP2 is an expression vector encoding an Ha-Ras/SREBP-2(473-1141) fusion protein with two NH2-terminal HSV epitope tags under control of the HSV thymidine kinase promoter (10). pTK-HSV-BP2-Ras-T7 is an HSV thymidine kinase promoter-driven expression vector encoding an SREBP-2(14-1141)/Ha-Ras fusion protein flanked at the NH2 terminus by two tandem HSV epitope tags and at the COOH terminus by three tandem copies of an epitope derived from the T7 major capsid protein (9). pCMV-SCAP is a cytomegalovirus promoter-driven expression vector encoding hamster SCAP that is similar to pCMV-SCAP (13) except that the expression vector was switched from pRc/CMV7SB to pcDNA3 (Invitrogen).
The expression vector pCMV-HSV-BP2(555-1141) encodes amino acids 555-1141 of human SREBP-2 preceded by an initiator methionine, two tandem copies of the HSV epitope (QPELAPEDPED), and two novel amino acids (ID) encoded by a sequence for the BspDI restriction site. pCMV-HSV-BP2(555-1141) was constructed as follows. First, pCMV-HSV-BP2 (see Ref. 13) was digested with BspDI and PmlI, and the 7.0-kb PmlI-BspDI fragment containing the HSV epitopes and amino acids 970-1141 of SREBP-2 was isolated. Second, the sequence corresponding to amino acids 555-969 of human SREBP-2 was amplified by PCR (8) of pTK-HSV-BP2 (see Ref. 21) with an NH2-terminal primer flanked by a BspDI site and a COOH-terminal primer flanked by a PmlI site. The resulting 1.3-kb BspDI-PmlI fragment was ligated to the above 7.0-kb PmlI-BspDI fragment to generate pCMVHSV-BP2(555-1141).
The expression vector pCMV-HSV-BP2(555-1141)-Ras-T7 encodes a fusion protein consisting of an initiator methionine, two tandem copies of the HSV epitope (QPELAPEDPED), two novel amino acids (ID) encoded by the restriction site for BspDI, amino acids 555-1141 of human SREBP-2, two novel amino acids (HM) encoded by the restriction site for NdeI, amino acids 2-189 of human Ha-Ras, and three tandem copies of the T7 epitope (9). pCMV-HSV-BP2(555-1141)-Ras-T7 was constructed as follows. First, pCMV-HSV-BP2 (see Ref. 13) was digested with ApaI to isolate a 7.3-kb fragment containing the HSV epitopes followed by human SREBP-2 (amino acids 14-505). pTK-HSV-BP2-Ras-T7 (see Ref. 9) was digested with ApaI to isolate a 2.6-kb ApaI-ApaI fragment encoding a fusion protein consisting of human SREBP-2 (amino acids 506-1141), human Ha-Ras (amino acids 2-189), and three tandem copies of the T7 epitope. The fragments were ligated to generate an intermediate construct. Second, this intermediate construct was digested with BspDI and PmlI, and the resulting 7.1-kb fragment was ligated with the 1.3-kb BspDI-PmlI PCR fragment described above to generate pCMV-HSV-BP2(555-1141)-Ras-T7.
The expression vector pCMV-SCAP(732-1276)-T7 encodes a fusion protein
consisting of an initiator methionine, amino acids 732-1276 of hamster
SCAP, and three tandem repeats of the T7 epitope.
pCMV-SCAP(732-1276)-T7 was constructed as follows. First, the sequence
corresponding to amino acids 732-910 of SCAP was amplified by PCR of
pCMV-SCAP (13) with a pair of primers,
5-ATACTAGTACCATGGTGCTGTGCCCGCGGAACTAT-3
(encoding amino acids
732-738 of SCAP preceded by an SpeI site and an initiator
methionine) and 5
-GCTGAAGTCATAGCCAGAGTC-3
(encoding amino acids
904-910 of SCAP). The PCR fragment was cloned into the pNoTA/T7 vector
(5 Prime-3 Prime, Inc.) and digested with BamHI, which cuts
in the polylinker of the pNoTA/T7 vector, and NotI to
isolate a 0.57-kb fragment encoding amino acids 732-900 of SCAP.
Second, pCMV-SCAP(773-1276) (provided by Tong Yang, University of
Texas Southwestern Medical Center) was digested with BamHI and NotI, and the 0.38-kb fragment encoding amino acids
773-900 of SCAP was replaced with the BamHI-NotI
0.5-kb fragment encoding amino acids 732-900 (described above) to
yield the resulting plasmid pCMV-SCAP(732-1276). Third,
pTK-HSV-SCAP-T7 (see Ref. 13) was digested with ApaI, and
the resulting 1.0-kb fragment encoding amino acids 961-1276 of SCAP
and three repeats of the T7 epitope was used to replace amino acids
961-1276 of SCAP in pCMV-SCAP(732-1276).
The structures of the above plasmids were confirmed by sequencing all PCR fragments and all ligation joints.
Site-directed MutagenesisOligonucleotide mutagenesis was carried out with single-stranded uracil-containing DNA (22) using the Muta-gene Phagemid kit (Bio-Rad) as described previously (8). Each mutant was sequenced to confirm the mutation, and at least two independent clones of each mutant were independently transfected into 293 cells to confirm the results.
AntibodiesPolyclonal antibody IgG-R139 against hamster SCAP was produced by immunizing rabbits with a mixture of two fusion proteins, one encoding six consecutive histidines followed by amino acids 54-277 of SCAP and the other encoding six consecutive histidines followed by amino acids 540-707 of SCAP (13). Monoclonal antibody IgG-9D5 against hamster SCAP was produced by immunizing a mouse (23) with a fusion protein encoding six consecutive histidines followed by amino acids 540-707 of SCAP (13). The cDNAs encoding the histidine-tagged proteins were cloned into pET28a(+) vector (Novagen) and expressed in Escherichia coli, and the proteins were purified by Ni2+-Sepharose chromatography as described (24). Monoclonal antibodies IgG-2A4 against the basic-helix-loop-helix domain of human SREBP-1 (25), IgG-7D4 directed against hamster SREBP-2 (amino acids 32-250) (11), and IgG-1C6 directed against the COOH terminus of human SREBP-2 (amino acids 833-1141) (8) have been described in the indicated references. Other monoclonal antibodies were obtained commercially as described above.
Culture, Transfection, and Fractionation of 293 CellsMonolayers of human embryonic kidney 293 cells were set up on day 0 (4 × 105 cells/60-mm dish) and cultured in 8-9% CO2 at 37 °C in medium A (Dulbecco's modified Eagle's medium containing 100 units/ml penicillin and 100 µg/ml streptomycin sulfate) supplemented with 10% (v/v) fetal calf serum. On day 2, the cells were transfected with the indicated plasmids as described previously (8). Three h after transfection, the cells were switched to medium B (medium A containing 10% newborn calf lipoprotein-deficient serum, 50 µM compactin, and 50 µM sodium mevalonate) in the absence or presence of sterols (1 µg/ml 25-hydroxycholesterol plus 10 µg/ml cholesterol added in a final concentration of 0.2% ethanol) as indicated in the legends. Pooled cells from two dishes were used either for preparing cytosol and membrane fractions as described previously (10) or for the co-immunoprecipitation/immunoblot assay as described below.
Stable Transfection of CHO-7 Cells with SCAPCHO-7 cells (26) were plated on day 0 at a density of 5 × 105 cells/100-mm dish in medium C (a 1:1 mixture of Dulbecco's modified Eagle's medium and Ham's F-12 medium containing 100 units/ml penicillin and 100 µg/ml streptomycin sulfate) supplemented with 5% newborn calf lipoprotein-deficient serum (10). On day 1, cells were transfected with 5 µg of pCMV-SCAP/dish (pCMV-SCAP is a neo-containing expression vector encoding wild-type hamster SCAP; see above). On day 2, the medium was switched to medium B containing 700 µg/ml G418. The medium was changed every 2nd day until well defined colonies were evident on day 12-14. Colonies were isolated with cloning cylinders in the presence of 350 µg/ml G418. The resulting stable cell lines were analyzed by immunoblotting with anti-SCAP IgG-9D5, and the highest expressing line was selected for immunofluorescence analysis.
Co-immunoprecipitation/Immunoblot AssayCells from 2 dishes
of 293 cells were harvested, and the pooled cell pellet was solubilized
with 1 ml of Nonidet P-40 lysis buffer (50 mM Hepes-HCl at
pH 7.4, 100 mM NaCl, 1.5 mM MgCl2, 1% (v/v) Nonidet P-40, 1 mM phenylmethylsulfonyl fluoride,
10 µg/ml aprotinin, 10 µg/ml leupeptin, 5 µg/ml pepstatin A, 25 µg/ml N-acetyl-leucinal-leucinal-norleucinal (ALLN), and 1 mM dithiothreitol), passed through a 22.5-gauge needle 15 times, and extracted by rotating for 1.5 h at 4 °C. All
subsequent operations were carried out at 4 °C unless otherwise
stated. The cell extracts were clarified by centrifugation at
105 × g for 30 min in a Beckman TLA 120.2 rotor. An aliquot of the supernatant (0.2-1.5 mg of protein in
0.2-0.9 ml) was adjusted to a final volume of 1 ml with Nonidet P-40
lysis buffer and precleared by rotation for 1 h with either 20 µg of an irrelevant mouse monoclonal antibody IgG-2001 (see Ref. 27)
(for immunoprecipitation with monoclonal antibodies) or 20 µg of an
IgG fraction of nonimmune rabbit serum (for immunoprecipitation with a
polyclonal antibody) and 50 µl of Protein G-Sepharose beads. Rotation
was carried out with a Cole-Palmer Instrument Co. apparatus (model
7637) at 15-20 rpm in a 4 °C cold room. After centrifugation at
300 × g for 3 min, the supernatant was transferred to
a fresh tube, and immune monoclonal or polyclonal antibodies were
added. After rotating for 1.5 h, 50 µl of Protein G-Sepharose
beads were added, followed by rotation for 1.5-3 h, and centrifugation
at 300 × g for 3 min. The resulting supernatant was
transferred to a new tube and precipitated with five volumes of acetone
for 10 min at 20 °C, followed by centrifugation at 3000 × g for 15 min. The pellet was resuspended in 0.1 ml of buffer
A (10 mM Tris-HCl at pH 6.8, 100 mM NaCl, 1%
(v/v) SDS, 1 mM sodium EDTA, and 1 mM sodium
EGTA) and designated as the supernatant fraction of the
immunoprecipitate.
The pelleted beads containing the immunoprecipitate were washed on the
rotator with 1 ml of Nonidet P-40 lysis buffer for 16 h, followed
by four additional washes in Nonidet P-40 lysis buffer for 45 min each.
The washed beads were resuspended in 0.1 ml of 2 × buffer B
(1 × buffer B contains 30 mM Tris-HCl at pH 6.8, 3%
SDS, 5% (v/v) glycerol, 0.004% bromphenol blue, and 5% (v/v)
-mercaptoethanol) and boiled for 5 min. After centrifugation at
1000 × g at room temperature for 3 min, the
supernatant was transferred to a fresh tube and designated as the
pellet fraction of the immunoprecipitate.
Prior to SDS-PAGE, the immunoprecipitate pellet and supernatant fractions each received 25 µl of 5 × buffer B. They were then boiled for 5 min and subjected to SDS-PAGE and immunoblot analysis. The proteins were transferred to Hybond-C extra nitrocellulose filters (Amersham Corp.), which were incubated with one of the antibodies described above. Bound antibodies were visualized with peroxidase-conjugated affinity-purified donkey anti-mouse or anti-rabbit IgG using the SuperSignal CL-HRP Substrate System (Pierce) according to the manufacturer's instructions. Gels were calibrated with prestained molecular weight markers (New England Biolabs). Filters were exposed to ReflectionTM NEF-496 film (NEN Life Science Products) at room temperature for the indicated time.
Previous studies demonstrated that the full-length precursor forms
of the SREBPs are bound to membranes of the ER and nuclear envelope, as
measured by immunofluorescence staining of transfected cells (25, 28).
To determine whether SCAP is similarly localized, we prepared a line of
CHO cells that permanently expresses elevated levels of wild-type SCAP
as a result of transfection with an expressible cDNA. Staining of
these cells with a monoclonal antibody against SCAP revealed that the
protein is also located in membranes of the ER and nuclear envelope
(Fig. 1).
The diagram at the top of Fig. 2
illustrates the proposed orientation of SREBP-2 and SCAP in ER
membranes. The diagram also shows the postulated interaction between
the COOH termini of the two proteins, both of which are oriented toward
the cytoplasm. The proposed orientation of SREBP-2 is supported by
previously published studies that employed protease protection (8) and insertion of sites for N-linked glycosylation into the
lumenal loop (8, 9). The placement of the COOH terminus of SCAP on the
cytosolic face of the membrane is based on several lines of evidence:
1) protease protection experiments to be published elsewhere3; 2) the structural
resemblance of SCAP to HMG-CoA reductase, whose COOH-terminal domain
faces the cytoplasm (17-19); and 3) the demonstration in the current
paper that the COOH-terminal domain of SCAP interacts with the
COOH-terminal domain of SREBP-2, which is known to face the cytoplasm
(1). We show SCAP with eight membrane-spanning regions (13) by analogy
to HMG-CoA reductase (18), but we have no direct evidence for the exact
number, and hence the NH2 terminus of SCAP might be on
either side of the membrane.
Panels A and B of Fig. 2 illustrate the results of a co-immunoprecipitation assay designed to measure the interaction of endogenous SCAP with endogenous SREBP-1 and SREBP-2 in nontransfected CHO cells. Prior to the experiment, the cells were incubated in medium containing lipoprotein-deficient serum, which lacks sterols. In some cells the cleavage of SREBPs was further induced by addition of the HMG-CoA reductase inhibitor compactin or suppressed by addition of cholesterol plus 25-hydroxycholesterol. After solubilization with 1% Nonidet P-40, which preserves the SCAP·SREBP complex, cell extracts were incubated with IgG-R139, a polyclonal antibody directed against SCAP. The immune complexes were precipitated with Protein G-Sepharose, and the pellet and supernatant fractions were subjected to SDS-PAGE and immunoblotted with an antibody against SREBP-1 (panel A) or SREBP-2 (panel B). The pellets from the immunoprecipitations contained the precursor forms of SREBP-1 (panel A, lanes 4-6) and SREBP-2 (panel B, lanes 4-6). No SREBP was precipitated when a nonimmune antibody was substituted for the anti-SCAP (lanes 1-3 of panels A and B). In panel C we blotted the immunoprecipitates with an anti-SCAP antibody to confirm that SCAP was being precipitated by the anti-SCAP antibody.
The supernatants from the immunoprecipitations contained residual SREBPs that were not co-precipitated with the anti-SCAP antibody (lanes 10-12 of panels A and B). By comparing the intensities of the pellet and supernatant fractions by densitometry, we estimated that ~20% of the SREBP-1 precursor and ~40% of the SREBP-2 precursor were precipitated by anti-SCAP. The antibodies against SREBP-1 and -2 were directed against the NH2-terminal domains and thus they visualized the proteolytically processed mature NH2-terminal fragments of SREBP-1 and -2, which are localized in cell nuclei (bands denoted by M in Fig. 2). As expected, the amounts of these fragments were increased by incubation with compactin and decreased by sterols. Importantly, all of the NH2-terminal fragments were found in the supernatants, and none was precipitated with the anti-SCAP antibody.
The experiment of Fig. 2 revealed another important facet of the SREBP·SCAP interaction. The amounts of SREBP-1 and -2 that were co-immunoprecipitated with SCAP did not change under conditions of sterol depletion or repletion, even though the rate of proteolytic processing varied dramatically under these conditions. Thus, sterols do not seem to regulate SREBP processing by regulating the interaction between SCAP and SREBPs.
To gain more insight into the mechanism of the SCAP interaction with
SREBPs, we performed a series of experiments in human embryonic kidney
293 cells that were induced to express varying forms of epitope-tagged
SREBPs or SCAP as a result of transient transfection. Fig.
3 shows one such experiment in which the
cells were transfected with cDNAs encoding SCAP and/or a tagged
version of SREBP-2 with an NH2-terminal epitope tag
consisting of two copies of a short peptide derived from the herpes
simplex virus glycoprotein (HSV-tag). Cell extracts were precipitated
with anti-SCAP and blotted with an antibody against the HSV-tag on
SREBP-2 (Fig. 3, panel A). As expected, when the cells had
not been transfected with the HSV-SREBP-2 construct, we found no
immunoreactivity in the pellet (lane 1) or supernatant
(lane 4). When cells expressed only the tagged SREBP-2 but
not SCAP, the anti-SCAP precipitated only a trace amount of SREBP-2
(panel A, lane 2). This trace band was more
clearly visible on longer exposures (data not shown). In contrast, when
hamster SCAP was overexpressed together with SREBP-2, the anti-SCAP
antibody precipitated ~40% of the epitope-tagged SREBP-2 (compare
lanes 3 and 6 of panel A). In
panel B the immunoprecipitates were blotted with a
monoclonal anti-SCAP that detects transfected hamster SCAP but not the
endogenous human protein. This antibody gave a positive result in cells
transfected with the SCAP cDNA, confirming the immunoprecipitation
of transfected SCAP.
We showed previously that overexpressed wild-type SCAP stimulates
cleavage of SREBPs (13). The experiment shown in Fig. 4 was designed to determine whether this
stimulation requires the COOH-terminal domain. The design of the
experiment is based on three previous observations: 1) the
NH2-terminal domain of SREBPs can be replaced by an
irrelevant sequence, such as the Ras protein, without disrupting
sterol-regulated cleavage (10); 2) truncation of SREBPs at the COOH
terminus progressively abolishes sterol-regulated
cleavage2; and 3) overexpression of wild-type SCAP
stimulates cleavage of SREBPs, and it overcomes the suppressive effect
of sterols (13). 293 cells were transfected with a cDNA encoding a
chimeric form of SREBP-2 with an HSV-tagged Ras substituted for the
NH2-terminal domain. The cells were incubated with sterols,
and hence no HSV-Ras was released into the cytosol (lane 2).
When the cells were cotransfected with a cDNA encoding SCAP,
cleavage of the HSV-Ras/SREBP-2 fusion protein was stimulated, and the
HSV-tagged Ras was found in the cytosol (lane 3). When the
COOH terminus of the chimeric protein was truncated at residue 793 of
SREBP-2, which corresponds to the end of exon 12 (29), SCAP still
stimulated cleavage of the protein, but the degree of stimulation was
markedly reduced (compare lane 5 with lane 3 in
cytosol fraction). When the protein was further truncated at residue
588, which corresponds to the end of exon 9, SCAP no longer stimulated
proteolytic cleavage (lanes 6 and 7). The STOP
588 protein retains only 33 amino acids following the second
transmembrane domain. These data indicate that SCAP stimulates cleavage
of SREBP-2 only when the COOH-terminal domain is present.
Fig. 5 shows that SCAP interacts with
SREBP-2 only when the COOH terminus is present. 293 cells were
transfected with a cDNA encoding full-length SCAP plus a cDNA
encoding the HSV-Ras/SREBP-2 fusion protein that terminates at a
position corresponding to the COOH terminus of wild-type SREBP-2 (STOP
1142) or at the premature truncation sites that were described in Fig.
4 (STOP 793 and STOP 588). To increase the amounts of the uncleaved
precursors that are available for co-immunoprecipitation, we introduced
the R519A mutation, which retards cleavage at Site-1 (10). In
panel A of Fig. 5, the cell extracts were immunoprecipitated
with anti-SCAP and blotted with the antibody against the HSV-tag at the
NH2 terminus of the HSV-Ras/SREBP-2 fusion protein. In the
SCAP-transfected cells, significant amounts of the STOP 1142 construct
were co-immunoprecipitated with SCAP (lane 3), but we
detected only trace amounts of the STOP 793 construct (lane
5) and none of the STOP 588 construct (lane 7).
Panel B is a control immunoblot, which shows that similar amounts of SCAP were present in all three immunoprecipitates.
Panel C of Fig. 5 shows the results when the order of antibodies was reversed. In this case we precipitated with antibodies against the HSV-Ras/SREBP-2 fusion protein and blotted with anti-SCAP. Again, significant co-immunoprecipitation occurred only with the STOP 1142 construct (panel C, lane 3). We conclude from this experiment that the interaction of SCAP with SREBP-2 requires the COOH-terminal domain of SREBP-2.
To demonstrate directly the interaction of SCAP with the COOH-terminal
domain of SREBP-2, we transfected cells with cDNAs encoding SCAP
plus a fragment of SREBP-2 that includes only the COOH-terminal domain
(Fig. 6). In the first part of the
experiment (panel A), we produced the COOH-terminal fragment
of SREBP-2 (residues 555-1141) with or without a COOH-terminal
extension encoding full-length Ras plus three repeats of an epitope
derived from a bacteriophage T7 protein (T7-tag). Cell extracts were
immunoprecipitated with anti-SCAP and blotted with an antibody against
the COOH-terminal domain of SREBP-2. The untagged COOH-terminal domain
of SREBP-2 was found in the pellet, but only when SCAP was
co-transfected (compare lanes 2 and 3). A similar
result was obtained with the Ras-T7-tagged COOH-terminal fragment
(compare lanes 4 and 5). Panel B shows
that SCAP was detected in the immunoprecipitate when the SCAP cDNA
was co-transfected.
In panel C of Fig. 6, we reversed the order of immunoprecipitation. Cell extracts were precipitated with a combination of antibodies against Ras and the T7 epitope and blotted with anti-SCAP. SCAP was found in the pellet only when both cDNAs were transfected (panel C, lane 3). Panel D confirms that the tagged SREBP-2 fusion proteins were precipitated by the antibodies against the Ras and T7 tags.
Having demonstrated that the COOH-terminal domain of SREBP-2 mediates
the interaction with SCAP, we next set about to identify the domain of
SCAP that was required. For this purpose we transfected 293 cells with
the cDNA encoding the HSV-Ras/SREBP-2 fusion protein plus a
cDNA encoding the COOH-terminal domain of SCAP (residues 732-1276)
that was tagged with three copies of the T7 epitope. Panel A
of Fig. 7 shows the results when SCAP was
immunoprecipitated with the antibody against the T7-tag and SREBP-2 was
visualized by blotting with the antibody against the HSV-tag. The
Ras/SREBP-2 fusion protein was immunoprecipitated, but only when the
COOH terminus of SCAP was expressed (compare lanes 2 and
3 of panel A). Panel B is a control
immunoblot showing that the anti-T7 antibody precipitated the T7-tagged
COOH-terminal fragment of SCAP.
To rule out the possibility that the SREBP-2·SCAP complexes were forming after the cells were solubilized, we performed a mixing experiment (data not shown). Two dishes of 293 cells were transfected with pCMV-SCAP, and two separate dishes were transfected with pTK-HSV-Ras-BP2 plus pVAI as described in legend to Fig. 3. Cell extracts from the two separate transfections were prepared, mixed together, and incubated together for 5 h during the preclearing period and the immunoprecipitation with anti-SCAP. The pellet was immunoblotted with the antibody against the HSV-tag, and no immunoprecipitated Ras/SREBP-2 was visualized. In the same experiment the anti-SCAP antibody coprecipitated Ras/SREBP-2 in extracts of cells that were cotransfected simultaneously with the cDNAs for SCAP and Ras/SREBP-2.
The current results establish that SCAP forms a complex with the full-length precursor form of SREBP-2 in cultured cells and that formation of this complex correlates with the ability of SCAP to stimulate cleavage of SREBP-2 at the sterol-regulated site (Site-1). Complex formation is mediated by the COOH-terminal domains of SREBP-2 and SCAP, both of which are located on the cytosolic surface of the ER and nuclear envelope.
The conclusion that the SCAP·SREBP-2 interaction is necessary for Site-1 cleavage is based on the observation that truncations of SREBP-2 at positions that remove 349 or 554 amino acids from the COOH terminus progressively reduce Site-1 cleavage (Fig. 4) and simultaneously reduce the binding of SCAP (Fig. 5).
The interaction between SREBP-2 (or SREBP-1) and SCAP was observed in co-immunoprecipitation assays with nontransfected cells that express only the normal endogenous levels of these proteins (Fig. 2). It was also observed in extracts of transfected cells that overproduce both SCAP and SREBP-2 (Figs. 3 and 5). The complex could be precipitated with antibodies against SCAP (Figs. 2 and 3) or with antibodies against epitope-tagged SREBP-2 (Fig. 5C). The complex could also be precipitated when the transfected cells expressed only the COOH-terminal domain of either SCAP or SREBP-2 (Figs. 6 and 7), confirming that the COOH-terminal domains were responsible for the interaction. We believe that the complex forms by direct interaction between the COOH-terminal domains of SCAP and SREBP, but we cannot rule out the possibility that the two domains each interact with a third protein that bridges the complex. We also cannot rule out the possibility that the membranous domain of SCAP plays some role in the interaction with SREBPs, but this domain is clearly not essential for this interaction.
The involvement of the COOH-terminal domain of SCAP in this protein-protein interaction is consistent with the presence in this domain of at least four (and likely five) WD repeats (13). These repeat sequences have been shown crystallographically to mediate protein-protein interactions in heterotrimeric G proteins (15, 16), and they have been implicated biochemically in such interactions in several other proteins (14).
Although the SCAP·SREBP-2 interaction occurs on the cytoplasmic face of the membrane, it leads to cleavage of SREBP-2 at Site-1 on the lumenal side of the membrane. SCAP itself does not appear to be a protease, as indicated by its lack of sequence resemblance to known proteases and by its failure to cleave SREBPs in co-translation assays. It seems likely, therefore, that the SCAP·SREBP-2 complex forms a binding site for a third protein, a protease, whose active site faces the lumen of the ER. We are currently attempting to isolate sufficient amounts of the SCAP·SREBP-2 complex so as to permit detection of any additional components.
We do not know the fate of the SCAP·SREBP-2 complex after the SREBP-2 is cleaved. We have shown that the COOH-terminal fragment of SREBP-2 remains membrane-bound and is eventually degraded (8). It is possible that SCAP remains associated with this fragment and is degraded with it. Alternatively, SCAP may recycle by dissociating from the COOH-terminal fragment after cleavage, following which it may bind to another SREBP precursor molecule.
In untransfected cells about 20-40% of the SREBP-2 precursor was co-immunoprecipitated with SCAP, and the rest remained in the supernatant (Fig. 1). We believe that nearly all of the SCAP in the cell extract was precipitated, but technical problems prevent us from confirming this conclusion by showing a disappearance of SCAP from the supernatant. In the supernatant SCAP is very dilute, and the protein aggregates when we attempt to concentrate it prior to electrophoresis (see lanes 7 and 8 in Fig. 6C). The incomplete precipitation of SREBP-2 suggests that the amount of SCAP is rate-limiting in complex formation and that only 20-40% of the SREBP precursors are in a complex with SCAP at any one time. This hypothesis is supported by the observation that overexpression of SCAP stimulates the cleavage of endogenous SREBPs (13), which implies that the amount of SCAP is ordinarily rate-limiting. We cannot rule out the alternate possibility that all of the cell's SREBPs are in a complex with SCAP, but some of the complexes dissociate during detergent extraction, immunoprecipitation, or washing.
The experiment of Fig. 2 demonstrates that the amount of SCAP·SREBP-2 complex is not altered when SREBP-2 cleavage is stimulated by incubation with compactin, or inhibited by incubation with sterols. These data indicate that SCAP does not respond to sterols by dissociating from SREBP-2. Rather, sterols may cause SCAP to dissociate from an accompanying protease, rendering the SCAP·SREBP-2 complex incompetent to carry out proteolysis.
The experiment of Fig. 2 also shows that endogenous SREBP-1, as well as SREBP-2, is co-immunoprecipitated with an antibody against SCAP. All of the subsequent transfection experiments were performed with SREBP-2. We have recently performed similar experiments with transfected epitope-tagged SREBP-1a and have obtained similar results, namely that SREBP-1a forms a complex with SCAP and that the amount of this complex is markedly reduced when the COOH-terminal domain of SREBP-1a is truncated (data not shown).
We have shown previously that 25-RA cells produce a mutant form of SCAP(D443N), which is hyperactive in stimulating cleavage of SREBPs and which resists down-regulation by sterols (13). In experiments not shown, we have found that SCAP(D443N) is co-immunoprecipitated with SREBP-2 to the same extent as wild-type SCAP in transfected 293 cells in the presence of sterols. Thus, the D443N mutation does not alter the direct interaction of SREBPs and SCAP, but it must alter some other function that renders the complex a better substrate for the Site-1 protease.
The current results provide strong support to the notion that SCAP is a required component of the pathway that leads to sterol-regulated cleavage of SREBPs at Site-1. Studies are now under way to further test this hypothesis and to make use of the SCAP·SREBP-2 complex to isolate the sterol-regulated protease.
We thank Mark Daris for expert technical assistance, Wei-Ping Li for help with immunofluorescence, Xianxin Hua for providing the polyclonal anti-SCAP antibody, Lisa Beatty and Michael McKelvey for invaluable assistance with cultured cells, Clark Garcia for help in generating the monoclonal anti-SCAP antibody, Georgeanna Cantrell for excellent help with gel electrophoresis, and Jeff Cormier and Michelle Laremore for efficient DNA sequencing and oligonucleotide synthesis.