(Received for publication, August 27, 1996, and in revised form, November 20, 1996)
From the Department of Medicine, University of Chicago, Chicago, Illinois 60637
Apolipoprotein(a) (apo(a)), a large glycoprotein
with extensive homology to plasminogen, forms a complex with
apolipoprotein B100 (apoB100), which circulates in human plasma in the
form of lipoprotein(a) (Lp(a)). Evidence indicates that the association of apo(a) with apoB100 occurs in the extracellular environment. We have
reevaluated the possibility that apo(a)-B100 association can also occur
as an intracellular event through studies with HepG2 cells stably
transfected with an apo(a) minigene. Several lines of evidence support
this possibility. First, continued Lp(a) production was demonstrated
following incubation of transfected HepG2 cells with anti-apo(a)
antisera, conditions that effectively block the fluid-phase association
of apo(a) and apoB100 in vitro. Second, an apo(a)-B100
complex was detectable in Western blot analyses of transfected HepG2
lysates following immunoprecipitation with anti-apo(a) antisera. These
studies incorporated precautions to eliminate cell-surface attachment
of preformed apo(a)-B100 complexes to the low density lipoprotein
receptor and were conducted in the presence of the lysine analog
-aminocaproic acid, which precludes apo(a)-B100 association
occurring during the isolation and analyses. Third, the presence of an
intracellular apo(a)-B100 complex was demonstrated in lipoproteins
isolated from microsomal contents. Of particular significance was the
observation that this complex contained the precursor form of apo(a),
which is not secreted, in addition to the mature, recombinant form.
Finally, direct evidence was provided for the synthesis of a precursor form of apo(a) in a nascent intracellular complex with apoB100 following treatment of transfected HepG2 cells with brefeldin A plus
N-acetyl-leucyl-leucyl-norleucinal. Taken together, these data suggest that apo(a)-B100 association can occur as an intracellular event in a human hepatoma-derived cell line, raising important implications for the regulation of Lp(a) secretion from human liver.
Lipoprotein(a) (Lp(a))1 is a cholesterol-rich lipoprotein species found in the plasma of humans and other primates (1, 2). Lp(a) resembles a modified low density lipoprotein (LDL) particle in which a single molecule of apolipoprotein B100 (apoB100) is joined through covalent linkage to a single molecule of apolipoprotein(a) (apo(a)) (3). Apo(a) is a large and highly polymorphic glycoprotein containing between 12 and 51 copies of a cysteine-rich region, homologous to a region found in single copy in plasminogen, and which is referred to as kringle IV (KIV) (4-6). Apo(a) contains, in addition, sequences homologous to KV and the protease domain of plasminogen (4). Elevated levels of Lp(a) are an acknowledged risk factor for premature atherosclerosis (7, 8), and this association has generated considerable interest in the mechanisms that may regulate the plasma concentration of this lipoprotein (6, 9-11).
Analysis of the Lp(a) phenotype of liver transplant recipients implicates the liver as virtually the sole source of Lp(a) in humans (12). These findings are in accord with other studies in which apo(a) mRNA distribution was confined essentially to the liver in both humans and non-human primates (13-16). In addition, metabolic studies in humans suggest that the principal determinant of plasma Lp(a) concentration is the synthetic rate rather than catabolic clearance (17, 18). Taken together, these studies suggest that hepatic production of Lp(a) is the major determinant of plasma Lp(a) levels in humans. Despite the obvious relevance of this issue, however, comparatively little is known about the mechanisms that regulate hepatic apo(a) synthesis and secretion in humans.
In regard to Lp(a) assembly, the structural determinants of apo(a) that regulate its association with apoB100 have been examined by transient expression of apo(a) in HepG2 cells (19-21). These studies demonstrated secretion of free apo(a), which was capable of association with apoB100 in the culture medium to form an Lp(a) particle (19-21). An important feature of these studies was the absence of an intracellular apo(a)-B100 complex as judged by the criterion of coimmunoprecipitation of apoB100 following the incubation of radiolabeled cell lysates with anti-apo(a) antisera (19, 20). Other workers have demonstrated synthesis and secretion of free apo(a) from primary cultures of baboon hepatocytes (22). These latter studies also detailed the absence of apoB coimmunoprecipitating with apo(a) from preparations of radiolabeled baboon hepatocyte lysates (22, 23). Further studies demonstrated convincingly that the interaction of baboon apo(a) with apoB100 takes place either at the cell surface or in the pericellular spaces following secretion from the hepatocyte (23). The suggestion that apo(a)-B100 association takes place following secretion from the liver is independently supported by studies from Hobbs and colleagues in which infusion of human LDL into apo(a) transgenic mice led to intravascular assembly of Lp(a) (24).
The opposing concept, namely that apo(a)-B100 association and Lp(a) formation can occur as an intracellular process in human liver, has been difficult to examine. In one study, workers were unable to demonstrate apo(a)-B100 association in homogenates of human liver samples using double-antibody enzyme-linked immunoabsorbent assays (ELISAs) (25). Studies from our laboratory, by contrast, demonstrated the presence of an intracellular apo(a)-B100 complex in primary human hepatocytes (26), but logistical limitations, coupled with the variable and generally low secretion rates of apo(a), ~ 3 orders of magnitude lower than that of apoB (26), have largely precluded a more widespread use of this approach.
In view of the importance of hepatic Lp(a) production, we have reevaluated the question of whether apo(a)-B100 association can be demonstrated to occur intracellularly. We have generated stably transfected clones of HepG2 cells expressing an apo(a) minigene containing the minimal critical structural domains of KIV required for maximal association with apoB100, as specified recently (27-29). Clones of these cells, in contrast to wild-type HepG2 cells, synthesize and secrete abundant quantities of apo(a) and Lp(a) and demonstrate the presence of apoB coimmunoprecipitating with apo(a) in lysates and in microsomal contents. In addition, the form of apo(a) found to coprecipitate with apoB100 from lysates includes the precursor species, which is not secreted. These data indicate that formation of an apo(a)-B100 complex in human liver-derived cells is accounted for, at least in part, by intracellular association.
Human apo(a) clones were a gift from John
McLean (Department of Cardiovascular Research, Genentech, Inc., South
San Francisco, CA). Monoclonal antibodies against human apoB were a
gift from Ross Milne (University of Ottawa Heart Institute). Human LDL
(30) and rabbit polyclonal antibodies against human Lp(a) were
generously supplied by Gunther Fless (University of Chicago). Goat
anti-human apo(a) antiserum was also purchased from Biodesign
International (catalog nos. K19867G and K19868G; Kennebunk, ME).
Protein A- and protein G-agarose were obtained from Boehringer
Mannheim. Tran35S-label (1000 Ci/mmol) was purchased from
ICN Biomedicals, Inc. (Costa Mesa, CA) and ECL Western blotting
detection reagents were obtained from Amersham. Brefeldin A was
purchased from Epicentre Technologies (Madison, WI). All other
chemicals and reagents were purchased from either
Sigma or Life Technologies, Inc.
The recombinant
apo(a) expression vector, pCH(a), illustrated in Fig. 1, contains the
signal sequence and 6 repeats of the KIV domain, as well as the KV and
protease domains. The plasmid was constructed by partial digestion,
with HindIII, of two apo(a) cDNA clones, -a18 and
-a41 (4). The resulting fragments provided a 174-bp 5
-clone
containing the 5
-untranslated region, signal sequence, and the first
93 bp of KIV repeat number 1 and a 3052-bp 3
-clone containing KIV
repeats 32 (minus 102 bp) through 37 (T5
T10, referring to the
nomenclature proposed by Morrisett et al.; Refs. 31 and 32),
KV, the protease domain, and 270 bp of the 3
-untranslated region. The
two fragments were annealed, the resulting construct consisting of a
333-bp fusion kringle (93 bp from KIV repeat 1 and 240 bp from KIV
repeat 32), followed by 3004 bp of apo(a) sequence (KIV repeats 33-37,
KV, protease domain, and 3
-untranslated region). This construct,
pCH(a), was sequenced, digested with EcoRI and
SphI, blunt-ended, and directionally subcloned into the
expression vector pCMV4 (gift from David Russell, University of Texas
Southwestern) as a 3237-bp fragment. The construct encodes a protein of
approximately 110 kDa (minus glycosylation) based upon the predicted
amino acid composition and was used in all the transfection
studies.
Cell Culture and Transfection
HepG2 cells were maintained in minimal essential medium supplemented with 1 mM pyruvate, nonessential amino acids (complete minimal essential medium) and 10% fetal bovine serum. McA-RH7777 cells were grown in DMEM containing 4 mM L-glutamine (complete DMEM) and 10% fetal bovine serum. For stable transfections, 1 × 106 cells/plate were cotransfected with either the apo(a) expression plasmid pCH(a) or vector control, and pSV2neo at a molar ratio of 20:1 using calcium phosphate precipitation (33). Stable transformants were selected with G418 (800 µg/ml for HepG2 cells and 400 µg/ml for McA-RH7777 cells), and individual colonies were transferred to 24-well dishes. Positive clones were screened by dot blot assay, and individual cell lines producing the highest level of apo(a) protein were selected for clonal expansion.
ELISAs for ApolipoproteinsCulture medium was collected after an 18-h incubation with serum-free medium. Apolipoprotein concentrations were determined in either an antigen capture (free apo(a) or apoB100) or a sandwich ELISA (coupled apoB100-apo(a)), and standardized using purified human Lp(a) and LDL-apoB100 (34).
Immunoblot Analysis of Intracellular ApoB-Apo(a) AssociationConfluent wild-type and transfected HepG2 cells were
washed three times with cold PBS and incubated at 4 °C for 1 h
with PBS containing heparin (10 mg/ml) to remove residual LDL bound to LDL receptors (35). 100 mM -aminocaproic acid (
-ACA)
was added to the incubation mixture and all buffers. This concentration was found to be 2 log orders in excess of that required to inhibit the
association of recombinant apo(a) with LDL, in vitro (see Fig. 1, lower panel). The cells were washed four times with
cold PBS and scraped into cold lysis buffer (20 mM
Tris-HCl, pH 7.0, 150 mM NaCl, 0.5% Nonidet P-40, 0.5%
bovine serum albumin, 5 mM EDTA, 0.5% Tween 20) containing
protease inhibitors (leupeptin (100 µM), aprotinin (450 µM), pepstatin (2 µM), EDTA (5 µM), phenylmethylsulfonyl fluoride (1 mM),
and benzamidine (1 mM)) and 100 mM
-ACA and passed several times through a 26-gauge needle. The cell lysate was
centrifuged at 16,000 × g for 15 min at 4 °C, and
aliquots of supernatants were immunoprecipitated with a polyclonal
anti-apo(a) antibody in the presence of
-ACA and electrophoresed
with or without DTT on a 4% SDS-PAGE gel. Apo(a)-reactive proteins
were transferred to a PVDF membrane and immunoblotted with a monoclonal antibody to apoB (1D1).
Transfected HepG2 cells
were maintained in serum-free media with 0.1 times the normal
concentration of methionine and cysteine, together with 150 µCi/ml
Tran35S-label, and incubated for periods of either 6 or
20 h. The incubations were supplemented with (final concentrations
of) 1.5% bovine serum albumin (essentially fatty acid free)/0.8
mM oleic acid. This labeling mixture (containing
approximately 10 µg/ml apo(a), as determined by ELISA) was spiked
with either goat anti-human apo(a) (50 µg/ml) or normal goat serum.
Culture medium was collected with protease inhibitors and 100 mM -ACA, followed by incubation at 4 °C for 4 h
with protein G-agarose. The protein G-agarose beads were washed three
times with 50 mM Tris, pH 7.4, 0.65 M NaCl, 20 mM EDTA, 1% Triton X-100, 1% sodium deoxycholate, 0.1% SDS, and two times with distilled water. Protein G-bound-apo(a) complexes were eluted in gel sample buffer and analyzed by 4-12% SDS-PAGE, followed by fluorography or immunoblotting. Transfected McA-RH7777 cells were radiolabeled under identical conditions for
20 h with 150 µCi/ml Tran35S-label, and aliquots of
labeled medium (containing approximately 7 µg/ml apo(a) as determined
by ELISA) were mixed for 2 h at 37 °C with human LDL (~10:1
(w/w) apoB:apo(a)) in the presence of either goat anti-apo(a) (50 µg/ml) or normal goat serum. Immune complexes were bound to protein
G-agarose as described above and, where indicated, further
immunoprecipitated with an anti-apo(a) antibody and analyzed by
SDS-PAGE.
Cells
were washed three times with ice-cold PBS and biotinylated for 15 min
with 0.62 mg/ml NHS-LC-biotin (Pierce) in PBS (36). The biotinylation
buffer was removed, fresh biotin added, and the cells incubated for
another 15 min. The cells were washed three times in cold PBS,
following which PBS containing 100 mM -ACA and 10 mg/ml
heparin was added, and the cells were rotated at 4 °C for 1 h.
The cells were lysed and immunoprecipitated with polyclonal antisera
against either apo(a) or apoB, containing 100 mM
-ACA,
followed by electrophoresis. Biotinylated apo(a)- and apoB-reactive
proteins were transferred to a PVDF membrane, and the immunoblots were
incubated in streptavidin-horseradish peroxidase conjugate, followed by
detection with ECL.
Cells were washed
four times with ice-cold PBS and scraped in homogenization buffer (10 mM Tris, pH 7.4, 250 mM sucrose) containing 100 mM -ACA and protease inhibitors. The cell suspension was homogenized with a tight-fitting pestle in a Dounce homogenizer at
0 °C. The homogenized sample was centrifuged two times at 10,000 rpm
for 10 min at 4 °C and then subjected to ultracentrifugation at
40,000 rpm for 30 min at 4 °C in a Beckman 50.3 Ti rotor to collect
microsomal membranes, as described (37). The membrane fraction was
rinsed two times with homogenization buffer, lysed at 4 °C in
hypotonic sodium carbonate buffer, pH 11.3 (37), containing 100 mM
-ACA, and dialyzed overnight at 4 °C against PBS
with 100 mM
-ACA. After the density was adjusted to 1.21 g/ml with solid KBr, the sample was ultracentrifuged at 100,000 rpm for
16 h at 4 °C in a Beckman TL100 ultracentrifuge. The top 150 µl was collected and lipoproteins precipitated with fumed silica
(38). Electrophoresis and subsequent Western blot analysis of the
precipitated lipoproteins were performed as detailed above. For
radiolabeling experiments, the cells were pulsed for 10 min with 250 µCi/ml of Tran35S-label and chased for another 10 min.
The cells were alkylated for 10 min on ice by adding 50 mM
iodoacetamide in PBS. After washing three times in cold PBS, the cells
were scraped into homogenization buffer as described above and total
microsomes prepared. Intramicrosomal lipoproteins floating at
d < 1.21 g/ml were immunoprecipitated with anti-apo(a)
antisera and examined by SDS-PAGE and fluorography.
Transfected McA-RH7777 cells were incubated for 1.5 h in methionine- and cysteine-free DMEM containing brefeldin A (5 µg/ml), followed by a 10-min pulse in the same medium containing Tran35S-label (250 µCi/ml). After the pulse, chase conditions were initiated by removing labeling medium and adding chase medium containing 10 mM methionine and 3 mM cysteine and brefeldin A for up to 2 h. At each time point, the cells were washed three times with cold PBS and scraped into cold lysis buffer (50 mM Tris, pH 7.4, 150 mM NaCl, 5 mM EDTA, 0.5% Triton X-100, 0.5% sodium deoxycholate) containing protease inhibitors and centrifuged at 10,000 rpm at 4 °C for 5 min. Aliquots of cell lysate supernatants were immunoprecipitated for apo(a).
Incubation of Human LDL with r-Apo(a) from Brefeldin A-treated Transfected McA-RH7777 CellsCells were pulse-labeled and chased in the presence or absence of brefeldin A as described above. After 120 min of chase, cell monolayers were washed three times with cold PBS and scraped in 1 ml of cold PBS. Cell lysates were passed three times through a 23.5-gauge needle and clarified by centrifugation at 10,000 rpm at 4 °C for 5 min. Aliquots of cell lysate supernatants containing equal amounts of trichloroacetic acid-precipitable radioactivity were incubated with h-LDL (1.5 µg of protein) at 37 °C for 1.5 h, followed by immunoprecipitation with anti-apo(a) antisera, SDS-PAGE, and fluorography.
Brefeldin A and N-Acetyl-leucyl-leucyl-norleucinal (ALLN) Treatment of Transfected HepG2 CellsTransfected HepG2 cells were
preincubated and radiolabeled for 1 h in medium containing either
brefeldin A (5 µg/ml) and/or ALLN (calpain inhibitor I; Boehringer
Mannheim, 40 µg/ml) and 250 µCi/ml Tran35S-label. The
cells were lysed in HBS buffer (50 mM HEPES, pH 7.5, 200 mM NaCl) containing 2% sodium cholate, 100 mM
-ACA, and protease inhibitors. Lysates were immunoprecipitated with
goat anti-apo(a) antisera. For sequential immunoprecipitations, cell
lysates were first immunoprecipitated with goat anti-apo(a) antisera in
HBS buffer containing 1% sodium cholate, 0.5% Triton X-100, and 100 mM
-ACA, following which 0.1 ml of HBS buffer (50 mM HEPES, pH 7.5, 200 mM NaCl) containing 1%
SDS was added to the protein G-agarose beads and heated at
90-100 °C for 5 min. 1 ml of HBS containing 1% Triton X-100 and
100 mM
-ACA was then added to the immunoprecipitation reaction. After centrifugation, the supernatant was used for
recapture-immunoprecipitation with a rabbit polyclonal antibody to
apoB100. Normal, preimmune goat serum was used as a control for the
first immunoprecipitation. All immunoprecipitates were analyzed by
SDS-PAGE followed by fluorography.
The highest producing clones of stably transfected HepG2 (2.15) and McA-RH7777 cells (8.2) were selected for further study. Culture media from the HepG2 clone demonstrated the presence of both apo(a) and Lp(a) as determined by ELISA (Table I). The relative distribution of apo(a), as inferred from both the ELISA data and by Western blot analysis of conditioned culture media (Fig. 1, lower panel, A), reveals that the majority (~70%) of apo(a) is unassociated with apoB100. Accumulation of apo(a) exceeded that of apoB (Table I), although apoB accumulation was comparable between the 2.15 clone and vector-transfected HepG2 cells (Table I).
|
Studies in primary baboon hepatocytes have
demonstrated that the association of apo(a) and apoB100, and hence
Lp(a) production, is blocked by incubation with anti-apo(a) antisera
(23). These conditions were applied to transfected HepG2 cells in order
to determine whether Lp(a) assembly, as judged by the criterion of coimmunoprecipitation of apoB100 with apo(a), is eliminated in the
presence of anti-apo(a) antisera. Such a finding would imply that Lp(a)
assembly in HepG2 cells, like in baboon hepatocytes, reflects
exclusively extracellular association. Accordingly, transfected HepG2
cells were radiolabeled for either 6 or 20 h in the presence of
anti-apo(a) antisera. Immune complexes isolated from the media demonstrated a coimmunoprecipitating band with the anticipated mobility
of apoB100 (Fig. 2A, lanes 2 and
3). The identity of this band was confirmed by Western blot
analysis of the immunoprecipitate using an anti-apoB antibody (Fig.
2A, lane 4). To establish that the conditions
used fully inhibit fluid-phase association of apo(a) and apoB100,
radiolabeled culture medium from transfected McA-RH7777 cells was
incubated (with or without antisera) for 2 h at 37 °C with
human LDL. These conditions allow maximal association of apo(a) and
apoB100 in vitro (see Fig. 1, lower panel,
A). Aliquots of the medium were analyzed under nonreducing
conditions, the results demonstrating that incubations performed in the
presence of anti-apo(a) antisera completely blocked apo(a)-B100
association (Fig. 2B, compare lanes 2 and
3). Repeated immunoprecipitation of the supernatant from
lane 3 with anti-apo(a) antisera failed to recover
additional apo(a) (Fig. 2B, lane 4), indicating
that the initial incubations were conducted under conditions of
antiserum excess. Accordingly, the results of the experiments shown in
Fig. 2A are inconsistent with the hypothesis that a complex
containing apo(a) and apoB100 arises exclusively from extracellular
association. Comparison of apoB100 cpm coimmunoprecipitated with apo(a)
from the media of radiolabeled, transfected, HepG2 cells incubated either in the presence or absence of anti-apo(a) antisera revealed that
62 ± 16% (n = 6) of the apoB was resistant to
inhibition of fluid-phase association, implying an origin of the
apo(a)-B100 complex that is inaccessible to apo(a) antiserum.
Coimmunoprecipitation of Apo(a) and ApoB100 from Lysates of Transfected HepG2 Cells: Exclusion of Cell-surface Association as a Major Source of the Complex
Transfected HepG2 cells were washed
extensively and incubated for 1 h with heparin (10 mg/ml),
conditions demonstrated to remove residual LDL and also to prevent
preformed complexes of apo(a)-B100 binding to LDL receptors (39). In
addition, 100 mM -ACA was included in all the incubation
and immunoprecipitation steps to prevent any artifactual association of
apo(a) and apoB100 that might possibly occur during the analysis
itself. Cell lysates were immunoprecipitated with anti-apo(a) antisera,
followed by Western blotting of the immune complex with an anti-apoB100
monoclonal IgG. This experiment revealed the presence of an apo(a)-B100
complex, which dissociates upon reduction, producing an immunoreactive apoB100 band of the anticipated mobility (Fig. 3). These
results thus reinforce the observation that a covalent complex of
apo(a) and apoB100 originates from transfected HepG2 cells independent of any potential association in the media.
In view of the findings of White et al. (23), demonstrating
that Lp(a) assembly occurs at the cell surface of baboon hepatocytes, experiments were conducted to evaluate this process in transfected HepG2 cells. Cell-surface biotinylation was undertaken in confluent monolayers of transfected HepG2 cells, which were then washed and
incubated with -ACA ± heparin as described above. Cell lysates were prepared and separate immunoprecipitations performed for apo(a)
and apoB. Under these conditions, coimmunoprecipitating bands that have
a cell-surface origin will be biotinylated and can be detected in
Western blots using streptavidin-HRP. Apo(a) immunoprecipitated from
lysates prepared without heparin treatment demonstrated a
coprecipitating apoB100 band, confirming the presence of a cell
surface-associated apo(a)-B100 complex (Fig. 4). By contrast, no coprecipitating apoB100 band was found when apo(a) immunoprecipitations were performed on cells incubated in the presence
of heparin (compare + and
a lanes, Fig. 4).
Heparin treatment greatly reduced the recovery of apoB100 (compare
B lanes + and
heparin), confirming
previous observations (35) that a large proportion of the cell-surface
apoB is found in association with LDL receptors from these HepG2 cells;
importantly, however, no coprecipitating apo(a) band was seen with the
apoB100 immunoprecipitations. Taken together, these experiments suggest
that any apo(a)-B100 complexes present on the cell surface can be
virtually eliminated with a combination of heparin and
-ACA
treatment. This observation, coupled with the demonstration (see Fig.
3) that an apo(a)-B100 complex is detectable in cell lysates prepared
from HepG2 cells incubated under conditions (heparin +
-ACA) that
minimize any possible contribution of preformed, surface-associated
apo(a)-B100 complexes, further supports the possibility of an
intracellular source of the apo(a)-B100 complex.
Demonstration of an Apo(a)-B100 Lipoprotein Complex Isolated from Microsomal Contents
In order to pursue the possibility that an
apo(a)-B100 complex might represent de novo intracellular
synthesis, microsomes were prepared from transfected HepG2 cells and
the content lipoproteins isolated at d < 1.21 g/ml.
These lipoproteins were adsorbed to silica and subjected to SDS-PAGE
and Western blotting with antisera specific for either apo(a) or
apoB100. Apo(a) was demonstrated in a covalent complex with apoB100, as
evidenced by the presence of an apo(a)-immunoreactive band in the
nonreduced sample (Fig. 5A, Micr.
). Interestingly, upon reduction of this complex with DTT, there
appeared two apo(a)-immunoreactive bands, one of which was of a size
compatible with the precursor form of the protein and was not
detectable in culture medium (Fig. 5A; see also Figs. 6 and 8). A corresponding complex of apo(a)-B100 was
detectable with anti-apoB100 antisera (Fig. 5B); this band
disappeared upon reduction of the complex with DTT. These results,
demonstrating the presence of a covalent apo(a)-B100 complex that
includes the precursor form of apo(a), provide further support for the
possibility of an intracellular source of this complex, since the
precursor form of apo(a) is not secreted from the cell. This experiment was also undertaken following a brief (10 min) radiolabel in order to
identify the newly synthesized precursor form of apo(a). In addition,
cell lysates were prepared following alkylation in order to prevent
disulfide bond formation during preparation of the microsomes. The
results of this experiment (Fig. 5C) confirm the presence of
apoB100 coimmunoprecipitating with the (newly synthesized) precursor
form of apo(a) from microsomal contents. Fig. 5D shows the
absence of apoB100, in control immunoprecipitations with wild-type HepG2 cells, generated with anti-apo(a) antisera.
The Precursor Form of Apo(a) Is Competent to Associate with ApoB100 in Vitro
Identification of the precursor apo(a) protein in a
lipoprotein complex with apoB100, isolated from microsomal contents,
strongly implies the possibility of an intracellular origin for this
complex. In order to investigate this possibility further, evidence was sought for the ability of the precursor form of apo(a) to associate with LDL-apoB100 following in vitro incubations. Stably
transfected McA-RH7777 cells were radiolabeled in the presence or
absence of brefeldin A in order to trap the precursor form of apo(a)
within the endoplasmic reticulum (40). As shown in Fig. 6A,
immunoprecipitation of apo(a) from control cells demonstrates the
expected precursor-product distribution with time following
pulse-chase. Cells radiolabeled in the presence of brefeldin A
demonstrate only the precursor form of the protein (Fig.
6B). Cell lysates were prepared under these conditions and
examined for their ability to assemble an apo(a)-B100 complex. As shown
in Fig. 7A, assembly of a covalent complex
was seen with the precursor form of apo(a) as well as the mature
recombinant apo(a). These data thus establish the potential for
apo(a)-B100 complex formation in vivo with the precursor
form of apo(a).
A Newly Synthesized, Precursor Form of Apo(a) Associates with ApoB100 in HepG2 Cells
In order to demonstrate conclusively that the precursor form of apo(a) actually assembles into a complex with apoB100 in vivo, further experiments were performed using the 2.15 clone of transfected HepG2 cells. The purpose of these experiments was to demonstrate the presence of newly synthesized apoB100 in coimmunoprecipitations performed with anti-apo(a) antisera as a measure of intracellular complex formation. In order to maximize the possibility of detecting apoB100, these experiments were performed in the presence of the calpain protease inhibitor ALLN, which has previously been demonstrated to reduce the intracellular degradation of apoB100 (41). Accordingly, cells were radiolabeled in the presence of either ALLN alone or ALLN plus brefeldin A and immunoprecipitations performed using anti-apo(a) antisera. Cells incubated with ALLN alone demonstrated both the precursor and mature recombinant apo(a) protein, while cells incubated with the combination of ALLN plus brefeldin A demonstrated only the precursor apo(a) form (Fig. 8A). In both instances a faint coimmunoprecipitating band, consistent with apoB100, was demonstrated (Fig. 8A). No apoB100 band could be detected in the absence of ALLN (data not shown). Subsequent experiments were undertaken using sequential immunoprecipitation in order to confirm the identity of the coimmunoprecipitating band as apoB100. These experiments demonstrate conclusively that apoB100 coprecipitates with the precursor form of apo(a) from cell lysates of ALLN plus brefeldin A-treated HepG2 cells (Fig. 8B). The demonstration of an apo(a)-B100 complex in brefeldin A-treated HepG2 cells implies that formation of this complex may be a very early event in the secretory pathway.
A considerable amount of information has accumulated in support of the hypothesis that Lp(a) assembly is an extracellular process (9, 42). The current results add an additional dimension to the understanding of Lp(a) assembly by demonstrating that the association of apo(a) and apoB100 can occur intracellularly in a human liver-derived cell line. It bears emphasis that the results of the current study in no way diminish earlier conclusions indicating that the association of apo(a) and apoB100 can take place in a cell-free system; indeed, the ability of our recombinant apo(a) to associate with apoB100 in this manner was confirmed. Nevertheless, the demonstration of intracellular apo(a) in complex with apoB100 raises important implications for the regulation of apo(a) secretion from human hepatocytes.
Several lines of evidence were sought to examine the possibility of intracellular association of apo(a) and apoB100. The following observations support this hypothesis. First, the association of apo(a) and apoB100 in the media of transfected HepG2 cells could not be blocked by the addition of anti-apo(a) antiserum. Second, apoB100 was found to coimmunoprecipitate with apo(a) from cell lysates prepared from transfected HepG2 cells. Both of these observations represent critical differences from previous reports using baboon hepatocytes (22, 23) and will be discussed in more detail below. Third, lipoproteins prepared from microsomal contents were found to contain a complex of apoB100 and apo(a) and, perhaps more importantly, the form of apo(a) demonstrated in this complex included the precursor, which is not secreted. Fourth and finally, synthesis of a precursor form of apo(a) that associates with apoB100 was demonstrated in transfected HepG2 cells treated with a combination of brefeldin A and ALLN. Each of these observations merits further consideration.
As alluded to above, previous work by White and co-workers demonstrated
that the addition of anti-apo(a) antiserum to primary cultures of
baboon hepatocytes completely blocked Lp(a) assembly, an observation
that strongly suggested apo(a)-apoB100 association was primarily an
extracellular event (23). The current studies applied a similar
experimental paradigm to transfected HepG2 cells, yielding results that
indicate continued apo(a)-apoB100 association. Precautions were taken
to insure that surreptitious association of apo(a) and apoB100 was not
a factor in these results, including the use of -ACA in all the
buffers. In addition, the antibody incubation conditions were
demonstrated to completely block fluid-phase association of apo(a) and
apoB100. The most reasonable interpretation of these results is that an
antiserum-inaccessible source of apo(a) is available for association
with apoB100. Among the possibilities considered in this regard are
cell membrane-associated and/or intracellular pools of apo(a) and
apoB100. In consideration of the first possibility, there is a clear
precedent for the cell-surface association of apo(a) on HepG2 cells
(39, 43). Recent studies by Tam and colleagues have demonstrated that
apo(a) binds to at least two classes of receptors on HepG2 cells. These
authors identified a high affinity (heparin-displaceable) binding site,
which corresponds to the LDL receptor, while the second is a low
affinity site, which is competed for by the presence of lysine analogs
and plasminogen (39).
The presence of recombinant apo(a) in association with apoB100 on the
surface of HepG2 cells was confirmed by the biotinylation studies,
which demonstrated a (coimmunoprecipitating/biotinylated)-apoB100 band
in immunoprecipitations of transfected HepG2 cell lysates performed
with anti-apo(a) antisera. This coimmunoprecipitating species was not
detectable, however, following heparin treatment, suggesting the
possibility that this apo(a)-B100 complex was attached to the LDL
receptor. It is important to emphasize that the Western blot analysis
presented in Fig. 3, demonstrating an apo(a)-B100 complex in HepG2 cell
lysates, was conducted following heparin incubation, thus rendering it
unlikely that the presence of a coimmunoprecipitating apoB100 band in
these lysates could be accounted for by the binding, to LDL receptors,
of apo(a)-apoB100 complexes formed in the media. In addition, all lysis
and immunoprecipitation steps were conducted in the presence of the
lysine analog -ACA, making it unlikely that the residual, low
affinity binding of apo(a) could result in the artificial generation of
a complex with apoB100 liberated from within heparin-inaccessible
domains in the cell membrane.
The current studies are the first to demonstrate the presence of a coimmunoprecipitating apoB100 band in transfected HepG2 cell lysates immunoprecipitated with anti-apo(a) antisera. Koschinsky and colleagues specifically examined the possibility of intracellular synthesis of Lp(a) in transfected HepG2 cells but were unable to detect coimmunoprecipitation of apoB100 in lysates immunoprecipitated with anti-apo(a) antisera (19, 20). Additionally, White and colleagues demonstrated that, despite the presence of mature apo(a) on the cell surface of baboon hepatocytes, apoB was never detectable in immunoprecipitations conducted with anti-apo(a) antisera (22, 23). Several differences in the current experimental model may account for some aspects of this fundamental discrepancy. Earlier studies in transfected HepG2 cells examined the issue of coimmunoprecipitation of apo(a) and apoB100 using an apo(a) construct with 17 repeats of KIV (19-21). The large size of the predicted protein expressed from this cDNA makes it difficult to distinguish apoB100 from apo(a), thus creating ambiguity in the interpretation of coimmunoprecipitating bands. An additional technical limitation may be that, at least in our hands, transfection of this size construct results in considerably lower apo(a) protein secretion into the media of either HepG2 or McA-RH7777 cells2 than found with the 6-KIV construct used in the current study. This impression is consistent with other studies in baboon hepatocytes by White and colleagues, who demonstrated an inverse correlation between apo(a) size and processing efficiency in the endoplasmic reticulum, resulting in lower secretion of the larger isoforms (44). Thus, an important technical advance in the present approach is the ability to express apo(a) at high levels and in a secreted form, which is readily distinguishable in size from apoB100. The sheer abundance of these protein species within lysates of transfected HepG2 cells may be one important factor in our ability to detect the presence of apoB100 in coimmunoprecipitations performed with anti-apo(a) antisera.
Further evidence in support of an intracellular origin of the apo(a)-B100 complex in transfected HepG2 cells was the demonstration of a precursor form of apo(a) in a complex with apoB100 isolated from microsomal lipoproteins. It is well established, from studies in both transfected HepG2 cells and in baboon hepatocytes, that the precursor form of apo(a) is found in the endoplasmic reticulum, where it undergoes glycosylation and additional processing to yield the mature species (22, 23). Of relevance to the current findings, however, is the observation that the precursor form of apo(a) is not secreted into the media (19-23). Proof that HepG2 cells synthesize an apo(a)-B100 complex, which includes the precursor form, was sought through experiments in which brefeldin A and ALLN were added to transfected HepG2 cells and radiolabeled cell lysates examined by sequential immunoprecipitation. The inclusion of ALLN was essential to the demonstration of an apoB100 band in co- and sequential immunoprecipitation experiments2 and suggests that the ability to detect small quantities of intracellular apoB in complex with apo(a) may be appreciably improved by limiting apoB degradation (41). In this context, it will be important to examine apo(a) synthesis and secretion and Lp(a) formation in this clone of HepG2 cells following exposure to oleate treatment, another mechanism proven to stabilize apoB100 (45, 46). Such studies are currently under way.
Several limitations in this experimental paradigm should also be emphasized so as to place in context the physiological significance of these findings. In particular, the relevance of intracellular apo(a)-B100 association using an apo(a) minigene containing only 6 repeats of kringle IV may have only limited significance to our understanding of Lp(a) assembly in human liver, where the minimum number of such repeats exceeds 12 (4-6). In addition, the demonstration of apoB100 coimmunoprecipitating with apo(a), despite the fact that apo(a) was never demonstrated to coimmunoprecipitate in complexes generated with anti-apoB antisera, remains unexplained. Among the possible explanations for this apparent paradox are that, compared to the intracellular pool of apoB, a relatively larger percentage of the intracellular apo(a) pool contains the apo(a)-B100 complex. This issue is difficult to resolve at present, since there are no physical or biochemical methods by which to isolate selectively the free and complexed forms of intracellular apo(a). A related issue is that the amount of apo(a) actually available for association with apoB100 is likely to be only a fraction of the total pool, based on the observation that prolonged, cell-free incubations with human LDL result in a maximum complex formation of 25-30% of the input apo(a) (Fig. 1). These values are comparable to those reported by other workers (19, 20) and have been interpreted to suggest that a large percentage of apo(a) is incorrectly folded with respect to the domains required for association with apoB100 (19, 20).
These reservations notwithstanding, the current results illustrate the feasibility of approaching questions concerning the structural requirements for the covalent association of apo(a) with apoB100, both intracellular and extracellular, and such studies form the focus of ongoing investigation.