J Biol Chem, Vol. 274, Issue 32, 22627-22634, August 6, 1999
Matrix Metalloproteinases-3, -7, and -12, but Not -9, Reduce
High Density Lipoprotein-induced Cholesterol Efflux from Human
Macrophage Foam Cells by Truncation of the Carboxyl Terminus of
Apolipoprotein A-I
PARALLEL LOSSES OF PRE-
PARTICLES AND THE HIGH AFFINITY
COMPONENT OF EFFLUX*
Leena
Lindstedt
,
Juhani
Saarinen§,
Nisse
Kalkkinen§,
Howard
Welgus¶, and
Petri T.
Kovanen
From the Wihuri Research Institute, Kalliolinnantie
4, 00350 Helsinki, Finland, the § Institute of
Biotechnology, Protein Chemistry Laboratory, University of
Helsinki, P. O. Box 56, FIN-00014 Helsinki, Finland, and the
¶ Division of Dermatology, Department of Medicine, Barnes-Jewish
Hospital at Washington University School of Medicine,
St. Louis, Missouri 63110
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ABSTRACT |
Matrix metalloproteinases (MMPs) have been
suggested to function in remodeling of the arterial wall, but no
information is available on their possible role in early atherogenesis,
when cholesterol accumulates in the cells of the arterial intima,
forming foam cells. Here, we incubated the major component responsible for efflux of cholesterol from foam cells, high density lipoprotein 3 (HDL3), with MMP-1, -3, -7, -9, or -12 at 37 °C
before adding it to cholesterol-loaded human monocyte-derived
macrophages. After incubation with MMP-3, -7, or -12, the ability of
HDL3 to induce the high affinity component of cholesterol
efflux from the macrophage foam cells was strongly reduced, whereas
preincubation with MMP-1 reduced cholesterol efflux only slightly and
preincubation with MMP-9 had no effect. These differential effects of
the various MMPs were reflected in their differential abilities to
degrade the small pre- migrating particles present in the
HDL3 fraction. NH2-terminal sequence and mass
spectrometric analyses of the apolipoprotein (apo) A-I fragments
generated by MMPs revealed that those MMPs that strongly reduced
cholesterol efflux (MMPs-3, -7, and -12) cleaved the COOH-terminal
region of apoA-I and produced a major fragment of about 22 kDa, whereas
MMPs-1 and -9, which had little and no effect on cholesterol efflux,
degraded apoA-I only slightly and not at all, respectively. These
results show, for the first time, that some members of the MMP family
can degrade the apoA-I of HDL3, so blocking cholesterol
efflux from macrophage foam cells. This expansion of the substrate
repertoire of MMPs to include apoA suggests that these proteinases are
directly involved in the accumulation of cholesterol in atherosclerotic lesions.
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INTRODUCTION |
One key factor in the prevention of atherosclerosis is considered
to be the ability of high density lipoproteins
(HDL)1 to remove excess
cholesterol from cholesterol-loaded macrophage foam cells. This is the
initial step of reverse cholesterol transport, along the pathway by
which cholesterol is carried from the peripheral tissues back to the
liver (1, 2). The major component of HDL is apoA-I, which, in addition
to a structural role, also has a biological function, playing the key
role in the initiation of reverse cholesterol transport (3). The mature
form of the apoA-I, a 243-amino acid protein with a molecular mass of
28 kDa, can combine with lipids to form stable structures of three
types: (i) small lipid-poor complexes; (ii) flattened discoidal
particles containing only polar lipids; and (iii) spherical particles
containing both polar and nonpolar lipids (as reviewed in Ref. 4). In the lipid-poor complexes with lipid contents of 10-40%, each particle contains only one apoA-I molecule, and this has a unique conformation with a much lower 
-helical content than the apoA-I in particles of
the other types. The discoidal particles consist of a single lipid
bilayer with repeating 22-amino acid helices of apoA-I which are
suggested to run around the disc in a belt-like fashion. In the
spherical particles, in contrast, the organization of apoA-I is
suggested to be disordered: turns of different apoA-I molecules may
be in contact with each other on the surface of the sphere.
The HDLs are a highly heterogeneous family of particles that have been
classified into several subgroups according to their density
(HDL2, HDL3), apolipoprotein (apo) composition
(apoA-I without A-II, apoA-I with apoA-II), or electrophoretic mobility (-migrating HDL, pre--migrating HDL) (5). In recent years, much
attention has been focused on the small fractions of lipid-poor HDL
particles (the small lipid-poor complexes; see above) that exhibit
electrophoretic pre- mobility (pre- HDL), in contrast to the
major spherical components of HDL, which exhibit mobility. The
total efflux of cholesterol from cells is believed to depend on two
components: one that is nonspecific, based on aqueous diffusion of
cholesterol from the cell's plasma membrane to fully lipidated apoA-I,
such as the mature HDL3 particles, and the other that is
specific and depends on interaction between lipid-poor apoA-I (pre-
HDL) and particular domains or proteins of the cell membrane (6, 7).
The pre- has been suggested to act as a shuttle, transporting free
cholesterol from the plasma membrane to the fully lipidated mature HDL
species (8-10).
A prerequisite for the action of HDL particles as efficient acceptors
of cellular cholesterol is their integrity. Thus, chemical modifications of HDL in vitro, such as copper-mediated
oxidation, treatment with trypsin or pronase, or glycation, all reduce
the efficiency with which HDL induce cholesterol efflux from cells (11-13). In a more physiological system, we have observed that mast
cells reduce a high affinity component of the cholesterol efflux
promoted by HDL3 from cholesterol-loaded macrophages in culture (14-16). This mast cell-mediated mechanism was found to be due
to proteolytic degradation of HDL3 apoproteins by the
neutral protease chymase, which is present in the exocytosed mast cell granules also found in atherosclerotic lesions. Most importantly, HDL3 function was lost after only a minimal degree of
proteolysis, suggesting that the high affinity process involves a minor
subfraction of HDL particularly susceptible to proteolytic cleavage
(14).
Matrix metalloproteinases (MMPs) are also present in atherosclerotic
lesions. These proteinases are a family of at least 16 distinct, but
structurally related, neutral proteases which are specialized in
degrading the various components of the extracellular matrix (17-19).
MMPs can be divided, according to their substrate specificity, into
four subgroups: collagenases, stromelysins, gelatinases, and
membrane-type MMPs. Here, we have examined the effects of some members
of the first three subgroups of MMPs: the fibroblast type collagenase
(MMP-1) of the group of collagenases; stromelysin (MMP-3), matrilysin
(MMP-7), and human metalloelastase (MMP-12) of the group of
stromelysins (or stromelysin-like MMPs); and 92-kDa gelatinase (MMP-9)
of the group of gelatinases (18, 19). Lipid-laden macrophages in
atherosclerotic lesions have been shown to produce several members of
the MMP family. These include MMPs-1, -2, -3, -7, - 9, and -12 (20-23). As demonstrated by Galis et al. (23), at least
some of these MMPs are proteolytically active in atheromas. However,
nothing is known about their possible involvement in cellular
cholesterol accumulation. Here we show that MMPs-1, -3, -7, and -12, but not MMP-9, can degrade the apoA-I of HDL3, and so block
cholesterol efflux from cholesterol-loaded human macrophages in
vitro.
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EXPERIMENTAL PROCEDURES |
Cells--
Human monocytes were separated from buffy coat cells,
allowed to differentiate to macrophages, and loaded with cholesterol, as described before (15).
Lipoproteins and Purification of ApoA-I--
Human low density
lipoprotein (d = 1.019-1.063 g/ml) and
HDL3 (d = 1.125-1.210 g/ml) were isolated
from fresh plasma of normal healthy donors by sequential
ultracentrifugation using KBr (24, 25). The low density lipoprotein was
acetylated by repeated additions of acetic anhydride (26).
[3H]Cholesteryl linoleate
(1,2(n)-[3H]cholesteryl linoleate, 30-60
Ci/mmol; Amersham Pharmacia Biotech) was incorporated into the
acetylated low density lipoprotein, as described (27), yielding
preparations in which [3H]cholesteryl linoleate/ng of
protein ranged from 30 to 100 dpm. ApoA-I was purified from the HDL
fraction by delipidation with ethanol:ether extraction, followed by
separation of apoA-I by anion exchange chromatography on a HiTrap Q
column (Amersham Pharmacia Biotech) (28, 29).
Metalloproteinases and Their Activation--
Recombinant MMPs-3,
-7, and -12 were expressed as active forms and purified as described
(30-32). MMPs-1 and -9 were purified (33) and activated with
phenylmercuric chloride (34), and activities were measured by the
[14C]gelatinase assay (35), 1 unit corresponding to
degradation of 1 µg of gelatin/min/µg of enzyme at 37 °C.
Proteolysis of HDL3 by
Metalloproteinases--
HDL3 (1.5 mg/ml) were incubated
with MMP-1, -3, -7, -12 (each 20 µg/ml), or MMP-9 (40 µg/ml) in 300 µl of 200 mM NaCl, 10 mM CaCl2,
50 mM Tris, pH 7.6, in the presence of 0.02 mM
butylated hydroxytoluene at 37 °C for the indicated time periods.
Proteolysis was stopped by adding EDTA to give a final concentration of
15 mM. Aliquots of the incubation mixtures were added to
macrophage foam cells, and other aliquots of the remainders were
delipidated (28) for mass analysis of the cleavage products.
Measurement of [3H]Cholesterol Efflux from
Macrophage Foam Cells--
Samples of proteolyzed or control
HDL3 (10 µg of total cholesterol/ml; each corresponding
to 25 µg of protein in control HDL3/ml) were incubated
for 6 h in dishes containing [3H]cholesterol-loaded
human monocyte-derived macrophage foam cells, as described previously
(15). Under these conditions, the efflux of
[3H]cholesterol was linear. After incubation, the medium
was collected, and its 3H radioactivity was measured by
liquid scintillation counting.
In preliminary experiments, the samples of HDL3 were
incubated with the MMPs for 72 h, the MMPs were then inhibited
with EDTA, and a sample of each incubation mixture was subjected to gel
filtration (Superose 12 HR 10/30-column, Amersham Pharmacia Biotech) to
separate the HDL3 from the enzymes. The cellular
cholesterol efflux induced by the treated HDL3 was similar,
irrespective of whether the MMPs had been separated from the
HDL3 or not. Therefore, in the experiments shown, the
separation step was omitted.
NH2-terminal Sequencing--
Protein samples were
separated in a 15% SDS-PAGE followed by electroblotting onto a
ProBlott PVDF membrane in 10 mM CAPS, pH 11, containing
10% methanol (36). Proteins were visualized by staining with Coomassie
Brilliant Blue, and bands of interest were cut out and loaded onto the sequencer.
Mass Spectrometry--
Matrix-assisted laser
desorption/ionization time-of-flight (MALDI-TOF) mass spectrometry was
performed on a BiflexTM time-of-flight instrument
(Bruker-Franzen Analytik) equipped with a nitrogen laser operating at
337 nm. The delipidated HDL3 and the MMP-generated
degradation products of HDL3 proteins were analyzed in the
linear positive ion delayed extraction mode, using sinapinic acid
(saturated solution in 0.1% trifluoroacetic acid, 30% acetonitrile
(TA)) (Aldrich) as the matrix. Samples were prepared by dissolving the
delipidated HDL3 (20 µg) in 100 µl of 0.1%
trifluoroacetic acid, 30% acetonitrile, and mixed 1:1 with matrix
solution. One µl of the mixture was spotted on the target plate, and
dried in a stream of warm air. All mass spectra were calibrated
internally, using the [M + H]+ and [M + 2H]2+ signals (m/z 28080.0 and
14040.5, respectively) of apoA-I.
Other Assays--
15% SDS-PAGE was performed in nonreducing
conditions according to Laemmli (37) and transferred to a
nitrocellulose membrane (38), and apoA-I was immunolocalized with
monoclonal anti-human apolipoprotein (Roche Molecular Biochemicals). A
low molecular weight marker from Amersham Pharmacia Biotech was used as
a standard. Cellulose acetate electrophoresis was performed with the
system of Helena Laboratories for lipoproteins (Titan III Lipo
membranes). The protein content was determined by the method of Lowry
et al. (39) with bovine serum albumin as standard. The
cholesterol and phospholipid contents of HDL3 were measured
using commercial kits (Cholesterol CHOD-PAP, Roche Molecular
Biochemicals, and phospholipids B, Wako Chemicals).
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RESULTS |
To generate [3H]cholesteryl ester-containing foam
cells, human monocyte-derived macrophages were incubated with
3H-labeled acetylated low density lipoprotein (25 µg/ml)
for 48 h. During incubation, the content of cholesteryl esters in
the macrophages increased from ~3 µg to ~90 µg/mg cell protein.
Subsequent incubation of the cells with HDL3 resulted in a
constant efflux of 3H radioactivity into the incubation
medium for at least 6 h, the time interval chosen for the efflux
experiments. We then preincubated HDL3 with MMP-3, -7, or
-12 for up to 2 h or with MMP-1 or -9 for up to 72 h, and
added the variously treated HDL3 preparations to human
macrophage foam cells (Fig. 1). After
pretreatment with any of the first three MMPs for only 30 min,
HDL3 rapidly lost its ability to induce cholesterol efflux,
which had fallen to about 20% of the initial value. In contrast, the
effect of MMP-1 on the efflux-inducing function of HDL3 was
much weaker. After incubation for 2 h, cholesterol efflux was only
slightly reduced, and the rate of efflux was significantly reduced only
after 72 h. Finally, when HDL3 was pretreated with
MMP-9, its ability to promote cholesterol efflux did not decrease even
after prolonged treatment with the active enzyme (12.5 units/300 µl).
When the variously pretreated HDL3 particles were added to
cholesterol-loaded mouse peritoneal macrophages, the results were
identical (not shown).
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Fig. 1.
Ability of metalloproteinases to inhibit
HDL3-induced cholesterol efflux from human monocyte-derived
macrophage foam cells. [3H]Cholesterol-loaded foam
cells were incubated with HDL3 (25 µg/ml) which had been
treated with MMP-1, -3, -7, -9, or -12 for the indicated times. After
incubation of the cells with the various HDL3 preparations
at 37 °C for 6 h, the 3H radioactivity found in the
culture medium was determined and plotted as a function of duration of
exposure to HDL3 for each MMP. Each point represents a mean
of triplicate incubations of macrophages obtained from three different
buffy coats.
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Fig. 2 compares the relation between the
concentration of HDL3 and the rate of
[3H]cholesterol efflux from macrophage foam cells. If
native HDL3 was added to the incubation medium, the rate of
cholesterol efflux rose rapidly at low concentrations of
HDL3. In striking contrast, addition of MMP-3-treated
HDL3 to the incubation system led to only a minimal
increase in cholesterol efflux, and this increase was not
dose-dependent at the HDL3 concentrations
tested. Thus, proteolytic treatment of HDL3 appeared to
abolish the high affinity component responsible for the rapid efflux of
cholesterol at low HDL3 concentrations.
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Fig. 2.
Relation of [3H]cholesterol
efflux from macrophage foam cells to the concentrations of
HDL3 and MMP-3-treated HDL3.
[3H]Cholesterol-loaded foam cells were incubated with the
indicated concentration of control HDL3 or with
HDL3, which had been treated with MMP-3 (0.02 mg/ml) for
2 h. After incubation of the cells with the HDL3
preparations at 37 °C for 6 h, the 3H
radioactivities found in the culture media were determined and plotted
as functions of HDL3 concentration. Values are mean ± S.E. (n = 6).
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Gel filtration of HDL3 on a Superose 12 column and analysis
of the eluate showed not only a major HDL peak, but also a minor peak
of small-sized particles (Fig.
3A). In cellulose acetate electrophoresis, these smaller particles showed pre- mobility, and
immunoblotting of the isolated particles after SDS-PAGE confirmed that
they contained apoA-I (not shown). We then treated aliquots of
HDL3 for 2 h with each of the MMPs separately.
Treatment with MMP-3, -7, or -12, i.e. with those MMPs that
had caused loss of the cholesterol efflux-inducing capacity of
HDL3, also resulted in disappearance of the small particles
(Fig. 3A). MMP-1, which had only a slight effect on the
cholesterol efflux-inducing capacity of HDL3, caused a
slight shift to the right in the elution of the small particles,
reflecting an apparent decrease in their size. But MMP-9, which did not
reduce the cholesterol efflux inducing capacity of HDL3,
also failed to reduce the quantity of the small particles. In a
separate experiment (Fig. 3B), HDL3 and
MMP-3-treated HDL3 were electrophoresed on a cellulose
acetate membrane, and this experiment also revealed the absence of
pre- particles from the MMP-3-treated HDL3 (Fig.
3B, lower panel). Finally, when purified apoA-I was treated
with MMP-7, which, like MMP-3, caused complete loss of the small
particles, its ability to promote cholesterol efflux was rapidly and
strongly reduced (Fig. 4)
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Fig. 3.
Analysis of matrix metalloproteinase-treated
HDL3 by gel filtration (A) and cellulose
acetate electrophoresis (B). HDL3
were incubated for 2 h with matrix metalloproteinases as indicated
under "Experimental Procedures" and applied to a Superose 12-gel
filtration column and eluted at a flow rate of 0.4 ml/min
(A). In a separate experiment, material of control
HDL3 and MMP-3-treated HDL3 was electrophoresed
on cellulose acetate and stained with Ponceau S (B).
Upper panel, control HDL3; lower
panel, MMP-3-treated HDL3.
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Fig. 4.
Ability of MMP-7 to inhibit apoA-I-induced
cholesterol efflux from human monocyte-derived macrophage foam
cells. [3H]Cholesterol-loaded foam cells were
incubated with apoA-I (25 µg/ml) which had been treated with MMP-7
for the indicated times. After incubation of the cells with the various
apoA-I preparations at 37 °C for 6 h, the 3H
radioactivity found in the culture medium was determined and plotted as
a function of duration of apoA-I exposure to MMP-7. Each point
represents a mean of triplicate incubations.
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Gel filtration study of HDL3 revealed that treatment of
HDL3 with those MMPs (MMPs-3, -7, and -12) that cause loss
of its cholesterol efflux-inducing capacity also caused loss of the
minor peak having pre- mobility. We therefore made a separate study of the capacities of the major and the minor peak to induce cholesterol efflux from macrophage foam cells. As shown in Table
I, with the material eluting in the minor
peak (1750 dpm) the ability to induce cholesterol efflux was slightly
less than half of that of the material eluting in the major peak (3990 dpm). The ability of the material in the minor peak to induce
cholesterol efflux was particularly high, considering that in the
HDL3 fraction the mass ratio of the minor to the major peak
was 1:10, and accordingly, in the incubation medium, the protein
concentration of the material derived from the minor peak was 2 µg/ml
and that of the material derived from the major peak was 20 µg/ml.
This result also demonstrated that, despite its high specific activity,
the material eluting in the minor peak did not account for the full
efflux capacity of the HDL3 fraction. Furthermore, as shown
in Table I, treatment of the material from the minor and the major
peaks with MMP-3 reduced their ability to induce cholesterol efflux to
similar extents. SDS-PAGE analysis of the major and the minor peaks
revealed that MMP-3 treatment resulted in almost complete degradation
of the apoA-I in the minor peak, but in only a minor degree of
degradation of the apoA-I in the major peak (Fig.
5).
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Table I
Effect of MMP-3 on the capacities of HDL3 size fractions to
induce cholesterol efflux from human monocyte-derived macrophage foam
cells
HDL3 was fractionated on a Superose 12 column into a major and
a minor peak (see Fig. 3). The materials from the major and the minor
peaks (each 1 mg/ml) were incubated separately for 2 h at 37 °C
in the absence (control HDL3) or presence of MMP-3
(MMP-3-treated HDL3). [3H]Cholesterol-loaded foam
cells were then incubated with material from the major peak (20 µg/ml) or the minor peak (2 µg/ml), i.e. using
quantities reflecting their approximate proportion in the bulk
HDL3. After incubation at 37 °C for 6 h, the 3H
radioactivity found in the culture medium was determined. Each value
represents a mean ± S.E. of triplicate incubations of macrophages
obtained from two different buffy coats (n = 6). The
p value (0.05) was determined by Student's t
test for paired samples, and was considered statistically significant.
Note that the major peak of control HDL3 contains particles
with both and pre- mobility, whereas the major peak of
MMP-3-treated HDL3 contains only particles with mobility.
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Fig. 5.
Proteolytic degradation by MMP-3 of material
contained in HDL3 and eluting from a Superose 12 column. The materials from the major and the minor peaks (each 1 mg/ml) were incubated separately at 37 °C with MMP-3 (0.02 mg/ml)
for 2 h. Aliquots were electrophoresed on 15% SDS-PAGE under
nonreducing conditions.
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To study further this unexpected observation that apoA-I degradation of
the major peak, even though of minor degree, caused a significant loss
(by half) of its cholesterol inducing ability, we reanalyzed the
material from the major peak of the control samples by cellulose
acetate electrophoresis and found that, in addition to the band, it
also contained a pre- band, revealing regeneration of pre-
particles. In sharp contrast, no pre- band was observed in the
MMP-3-treated material collected from the major peak. The regeneration
of pre- particles by the material eluting in the major peak, and
loss of this pre- regenerating ability after MMP-3 treatment,
provide plausible explanations for the observation that MMP-3 treatment
caused a dramatic loss of the cholesterol efflux inducing capacity,
which equaled the loss observed when the material eluting in the minor
peak was treated with MMP-3.
SDS-PAGE analysis of MMP-treated HDL3 revealed rapid
degradation of apoA-I during incubation with MMP-3, -7, or -12, i.e. with the enzymes that inhibited
HDL3-dependent cholesterol efflux from foam
cells (Fig. 6). These enzymes degraded
apoA-I (28 kDa) to forms with apparent molecular mass of 24-26 kDa and
to smaller fragments of approximately 14 and 6 kDa. In contrast, when
HDL3 was incubated with MMP-1, degradation products
appeared much less rapidly and, when HDL3 was incubated
with MMP-9, no degradation products appeared. In another experiment,
proteolysis with the various MMPs was continued for 72 h. SDS-PAGE
analysis of the degraded HDL3 preparations revealed the
following bands (Fig. 7): MMP-3 had
degraded almost all of the apoA-I without causing any apparent change
in apoA-II, the ~14-kDa fragment being strongly accumulated.
Similarly, the ~14-kDa fragment was enriched when HDL3
was incubated with two other efflux decreasing MMPs (7 or 12). MMP-1,
which decreased the HDL3-induced efflux only after prolonged incubation with HDL3, also caused enrichment of
the ~14-kDa fragment, and, in addition, smaller degradation products became visible. In contrast to MMPs-3, -7, and -12, MMP-1 also appeared
to degrade apoA-II. MMP-9, which had no effect on
HDL3-induced efflux even after incubation for 72 h
(see Fig. 1), appeared to degrade only apoA-II. A similar degradation
pattern was seen with another gelatinase, MMP-2, which also failed to
decrease HDL3-induced cholesterol efflux significantly
after incubation with HDL3 for 72 h (not shown). In
summary, the SDS-PAGE analysis suggests that apoA-II is more vulnerable
to gelatinases (MMP-2 and MMP-9) than apoA-I, but that this proteolysis
alone does not significantly reduce HDL3-induced
cholesterol efflux from macrophage foam cells.
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Fig. 6.
Proteolytic degradation of HDL3
by matrix metalloproteinases. HDL3 (1.5 mg/ml) was
incubated at 37 °C with MMP-1, -3, -7, -12 (0.02 mg/ml), or MMP-9
(0.04 mg/ml) for the indicated time periods. Aliquots were
electrophoresed on 15% SDS-PAGE under nonreducing conditions.
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Fig. 7.
Proteolytic degradation of HDL3
by matrix metalloproteinases for 72 h. HDL3 (1.5 mg/ml) was incubated at 37 °C with MMP-1, -3, -7, -12, or MMP-9
(0.04 mg/ml each) for 72 h. Aliquots were electrophoresed on 15%
SDS-PAGE under nonreducing conditions.
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Inspection of the time course studies of degradation and reduction in
cholesterol efflux ability shows that it is the first cleavages
converting apoA-I into 24-26-kDa fragments that lead to loss of efflux
ability. We therefore chose the larger fragments for more detailed
analysis. Using strategies based on MALDI-TOF mass spectrometry
combined with NH2-terminal sequencing, we identified the
MMP cleavage sites in apoA-I that produce fragments larger than 14 kDa.
The major fragments of apoA-I (14-26 kDa) from the MMP-3, -7, and
-12-treated HDL3, when subjected to
NH2-terminal sequencing, were all found to have the
NH2-terminal sequence of apoA-I (DEPPQ ... ) intact,
thus confirming that, with these MMPs, breakdown of apoA-I occurs at
its COOH terminus. Mass analysis (Table
II) of MMP-3-treated HDL3
yielded major signals at three m/z values over
14,000: m/z 28,080, 22,220, and 14,723 [M + H]+, corresponding to intact apoA-I, apoA-I cleaved at the
Glu191-Tyr192 bond, and apoA-I cleaved at the
Glu125-Leu126 bond, respectively. Mass analysis
of MMP-7-treated HDL3 yielded major signals at four
m/z values over 14,000: m/z
28,080, 24,650, 23,452, and 14,259 [M + H]+,
corresponding to intact apoA-I and apoA-I cleaved at the
Asp213-Leu214,
Thr202-Leu203, and
Pro121-Leu122 bonds, respectively. Mass
analysis of MMP-12-treated HDL3 yielded major signals at
six m/z values over 14,000:
m/z 28,079, 25,989, 24,637, 23,155, 22,211, and
14,254 [M + H]+, corresponding to intact apoA-I and
apoA-I cleaved at the Phe225-Lys226,
Asp213-Leu214,
His199-Leu200,
Glu191-Tyr192, and
Pro121-Leu122 bonds, respectively.
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Table II
Fragmentation of apoA-1 by MMPs-3, -7, and -12
Using strategies based on MALDI-TOF mass spectroscopy combined with
NH2-terminal sequencing, MMP cleavage sites in apoA-I that
produced fragments larger than 14 kDa were identified.
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Using gel filtration through a Superose 12 column, we then isolated
from HDL3 the minor peak of small sized particles, which showed pre- mobility in cellulose acetate electrophoresis (see Fig.
3, A and B), and separately treated aliquots of
this fraction with MMP-3 for 2 h. Importantly, after incubation
for as little as 15 min, 90% of the intact apoA-I in these small
particles had been converted into 24-kDa sized fragments, as judged by
SDS-PAGE analysis (Fig. 8). Mass analysis
of the MMP-3-treated pre- particles yielded major signals at three
m/z values over 14,000: m/z
28,080, 22,220, and 14,723 [M + H]+, corresponding to
intact apoA-I, apoA-I cleaved at the
Glu191-Tyr192 bond, and apoA-I cleaved at the
Glu125-Leu126 bond, respectively. The spectrum
was identical with that of MMP-3-treated total HDL3. In
sharp contrast, free apolipoprotein A-I isolated from lipoproteins was
rapidly degraded by MMP-3 without apparent preference of cleavage sites
(not shown).
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Fig. 8.
Proteolytic degradation by MMP-3 of material
contained in HDL3 and eluting from a Superose 12 column as
a minor peak. The material from the minor peak (0.9 mg/ml) was
incubated at 37 °C with MMP-3 (0.02 mg/ml) for the indicated time
periods. Aliquots were electrophoresed on 15% SDS-PAGE under
nonreducing conditions.
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Since proteolytic breakdown occurred at the COOH terminus of the
apoA-I, determination of the cleavage sites by direct sequence analysis
was not possible. The cleavage sites had to be deduced from the
combined information afforded by the NH2-terminal sequences and the masses of fragments. The assignment of the cleavage sites determined by MALDI-TOF mass spectrometry can be considered reliable, since the accuracy of the instrument in the mass range studied is
better than 0.05% (error less than ± 14 Da for 28 kDa protein). Thus, a combination of the known NH2-terminal sequences,
the protein sequences, and the fragment masses with the information
that the apoA-I did not contain post-translational modifications
provides sufficient data for deducing the COOH-terminal sequences by
mere calculation (see Table II).
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DISCUSSION |
The present study shows that several members of the MMP family are
able to degrade human HDL3, thereby dramatically decreasing its capacity to promote cholesterol efflux from cholesterol-loaded human monocyte-macrophages. MMPs-3, -7, and -12, which have broad substrate specificity (18), were the most efficient in degrading apoA-I; MMP-1, which has a more restricted substrate specificity, did
so far less efficiently, and MMP-9, which also possesses restricted substrate specificity, was unable to degrade apoA-I even during prolonged incubation. The present study also demonstrates that the
matrix metalloproteinases act chiefly on the COOH-terminal region of
apoA-I. The first degradation products split off by the enzymes, which
reduce HDL3-induced cholesterol efflux, are 22-26-kDa
fragments, and correspond to losses of the final 18-52 amino acids
(see Table II). This susceptibility of the COOH terminus to proteolysis
accords with previous findings in which limited degradation by other
enzymes (chymotrypsin, trypsin, elastase, subtilisin,
Staphylococcus V8 protease, and arginine C endopeptidase) produced 22-, 24-, and 26-kDa NH2-terminal fragments of
apoA-I (40-42).
The similarities in kinetics between the degradation of apoA-I and the
loss of the reverse cholesterol transport activity of HDL3
particles suggest that apoA-I was already inactivated by these first
cleavages in the COOH-terminal region. Similarly, Marcel and Frank
(43), using lipid-free or lipidated human apoA-I mutants, concluded
that the COOH-terminal domain of apoA-I is especially important for
promoting cholesterol efflux from cholesterol-loaded macrophages.
Another study using lipid-free apoA-I mutants has shown that induction
of phospholipid efflux and subsequent cholesterol efflux from HepG2
cells requires the presence of the 21 COOH-terminal amino acids (44).
The COOH terminus has also been shown to be essential for the
structural integrity of the adjacent regions of apoA-I (45). Similarly,
studies with the natural apoA-I (Pro165 
Arg) variant
have shown that this variant of apoA-I is a poor acceptor of
cholesterol from macrophages and adipocytes (46, 47). Von Eckardstein
et al. (47) suggested that the Pro Arg substitution in
position 165 eliminates a turn between two adjacent -helices and
so changes the orientation of all subsequent -helices. Since these
mutational changes in the COOH-terminal portion of apoA-I lead to
structural changes in the adjacent parts of the molecule, it has not
been possible to determine whether the reduction in cholesterol efflux
is caused by changes in the COOH terminus itself or by secondary
effects on the residual apoA-I molecule. Similarly, we cannot decide
whether the event responsible for the observed functional changes was
cleavage of the COOH-terminal region of apoA-I or possible secondary
changes in apoA-I structure.
This study adds a new substrate and potentially a new biological
function for MMPs -3, -7, and -12. These MMPs were able to cleave the
apoA-I in HDL3 at a substantial rate; incubation of HDL3 at a concentration of 1.5 mg/ml with any of the above
MMPs at a concentration of 0.02 mg/ml led to 70% loss of its
cholesterol efflux promoting ability within 15 min. It should be noted,
however, that such incubation does not lead to 70% loss of intact
apoA-I from the HDL3 particles. This discrepancy is not due
to changes in the lipid composition of these particles for, in the
MMP-modified HDL3 particles, the contents of total
cholesterol and phospholipid remained unchanged (data not shown). Nor
is it dependent on lecithin:cholesterol acyltransferase, since
inhibition of lecithin:cholesterol acyltransferase during proteolysis
by MMP-7 did not have any further effect on efflux. The
HDL3 samples had neither PLTP nor CETP activity, as measured by radiometric assays (48). The proteolyzed fragments of
apoA-I may also have competed for removal of cholesterol. To test this
possibility, we mixed intact HDL3 either with the entire MMP-7-treated HDL3 or with the MMP-7-treated minor peak of
HDL3, and added these two mixtures separately to macrophage
foam cells. As compared with the ability of intact HDL3
alone to induce cholesterol efflux, the effects of the mixtures were in
both cases additive, revealing that neither the proteolyzed
HDL3 as a whole nor the proteolyzed minor peak inhibited
the activity of the intact HDL3 (data not shown).
It may be that only a minor fraction of the particles in the
HDL3 preparation is capable of accepting cholesterol from
the cells, and that this minor fraction is more susceptible to
proteolysis than the bulk of the HDL3. Indeed, after
Superose 12-gel filtration, we found that the HDL3 fraction
contains minute amounts of small particles which showed pre-
mobility on cellulose acetate electrophoresis (see Fig. 3B).
The small particles disappeared very rapidly after treatment with
cholesterol efflux-reducing MMPs (MMPs-3,-7, and -12). Importantly,
this loss of the small particles was accompanied by reduction of the
high affinity component of cholesterol efflux from macrophage foam
cells (see Fig. 2). This accords with our previous findings that
exposure of the LpA-I-containing particles present in HDL3
and in plasma to a minimal degree of proteolysis by the neutral
protease chymase from exocytosed rat mast cell granules or from human
skin results in reduced high affinity efflux of cholesterol from
macrophage foam cells (15, 16). Interestingly, Mendez and Oram (49)
have shown that mild trypsin treatment, by proteolyzing a minor
trypsin-labile fraction of HDL, almost completely abolished
apolipoprotein-mediated cholesterol removal. Similarly, Kunitake
et al. (42) showed that the apoA-I in the pre- fraction
was more susceptible to proteolysis than in the particles.
Moreover, we found that after incubation with MMP-3 for as little as 15 min, 90% of the intact apoA-I in the small particles had been
converted into the 22-kDa sized fragments. Although the loss of the
small particles accords well with the rapid inhibitory effect of these
MMPs on the cholesterol efflux inducing ability of HDL3, we
cannot exclude the possibility that changes were present in other
subfractions of the ultracentrifugally isolated HDL3 as
well, but were not detected by the methods used in this study. A more
complete analysis of the proteolyzed subpopulations and correlation
with the loss of the cholesterol efflux promoting capacity of
HDL3 requires additional experiments.
The pre- fraction appeared to be in a state of balance with the
major HDL3 fraction. In fact, after separation of these two fractions by gel filtration, we repeatedly observed the appearance of a
peak containing the small particles in addition to the major HDL3 peak. Even multiple reisolation of the major peak
failed to produce a fraction without a pre- band. Only
HDL3 that had been floated through a KBr solution (1.21 g/ml) using high g forces (424,000 × g,
16 h), and analyzed immediately after reisolation, showed pure mobility. But after dialysis, a pre- band soon reappeared (within
4 h) reflecting the tendency of apoA-I to dissociate from the
spherical particles with mobility (data not shown). Whether apoA-I
dissociates spontaneously or in response to trace amounts of
pre--generating enzymes (PLTP or CETP) cannot be decided here. Since
we were unable to detect PLTP or CETP activities in the
HDL3 preparations, it likely that apoA-I dissociated
spontaneously from the major HDL3 fraction. This notion
accords with the suggestion of Mendez and Oram (49) that the
apolipoproteins in HDL that are most sensitive to proteolysis are
likely to be less tightly bound to phospholipids, and therefore can
dissociate more easily from the particle surface and mediate
cholesterol efflux. From the present findings, we infer that the MMPs
preferentially proteolyze the apoA-I molecules, which readily
dissociate from particles and form the pre- particles. Although
the quantity of pre- particles in the HDL3 preparations
was very small, their regeneration would make them potentially
significant cholesterol acceptors. Since pre- HDL are considered to
be the first acceptors of cellular free cholesterol (50), degradation
of the pre- particles and, in particular, inhibition of their
regeneration could significantly contribute to the observed inhibition
of the cholesterol efflux inducing ability of HDL3 by the MMPs.
Two reports have shown caseinolytic and gelatinolytic activity in
atherosclerotic areas (23, 51). Although the concentrations of MMPs are
unknown in the interstitial fluid of atherosclerotic lesions, MMP
concentrations have been measured in synovial fluids from arthritic
joints, which like atherosclerotic lesions, are inflamed tissues. Thus,
in the synovial fluid of patients with rheumatoid arthritis the
concentrations of MMPs-1,-8, and -9 ranged from 1 to 15 µg/ml (52),
that of MMP-3 ranged from 6 to 110 µg/ml, with a mean concentration
of 40 µg/ml (53). Importantly, synovial fluid from rheumatoid
arthritis patients demonstrated 100-fold higher levels of active MMP-3
than synovial fluid from control subjects (54). We performed additional
experiments in which the MMP concentration in the incubation medium was
progressively lowered, and found that incubation of HDL3
with even 2.5 µg/ml (i.e. about 1/10 of that used in the
other experiments) of trypsin-activated MMP-3 for 20 h at 37 °C
was sufficient for maximal reduction of the efflux promoting ability of
HDL3 from mouse macrophage foam cells. Our previous results
with mast cell chymase have also revealed that even a minute degree of
proteolysis of HDL3 can cause a dramatic decrease in its
ability to promote cholesterol efflux from macrophage foam cells (14).
It is also important to note that the foam cells in the atherosclerotic
lesions themselves produce MMPs (22, 55), and that some of the MMPs
secreted by the cell remain attached to the cell membrane during cell
migration (56). Thus, in the pericellular compartment on or near the
cell membrane, the local concentration of MMPs is likely to be high.
Also, to be able to induce cholesterol efflux, apoA-I has to come into
very close contact with or be attached to the cell membrane. In light
of the above considerations, the concentration of MMPs in relation to
that of apoA-I may be much higher near the cell membrane than in the
bulk of the extracellular fluid in the arterial intima. Thus, the
concentration of (active) MMPs would be adequate to prevent
apoA-I-dependent cholesterol efflux from the macropahge foam cells in atherosclerotic lesions.
The novel observations made in this study raise two questions. First,
does degradation of HDL3 by MMPs affect any of its other functions apart from its role as a cholesterol acceptor,
e.g. its action as an antioxidant, as a mitogen, or as an
anti-inflammatory agent (57-60)? Second, do other proteases present in
the aortic intima that are capable of cleaving apoA-I, such as plasmin,
thrombin, kallikrein, and elastase (42, 61, 62), also block cholesterol efflux? Interestingly, SDS-PAGE analysis of a major fibril protein purified from amyloid deposits in the aortic intima revealed two broad
bands corresponding to ~14 and <10 kDa, which were shown to be
NH2-terminal fragments of apoA-I (63). The mechanism by which these fragments were generated is unknown. One possibility is by
degradation of apoA-I by proteases in the intima. In our in
vitro studies, proteolysis of apoA-I by matrix metalloproteinases led to formation of fragments of ~14 kDa, and these fragments seemed
to be enriched during proteolysis. It is an intriguing possibility that
such MMP-derived fragments become enriched and are deposited in the
atherosclerotic intima. Taken together, elucidation of the effects of
matrix metalloproteinases, and possibly of other proteases, on apoA-I
and its cholesterol efflux promoting and other properties remains an
important challenge for future studies. The proteolytic modifications
of apoA-I may turn out to be of major importance in blocking the
physiological functions of apoA-I in the arterial intima, such as
mediation of the initial steps of reverse cholesterol transport from
human atherosclerotic lesions consisting of numerous macrophage-derived
foam cells.
| |
ACKNOWLEDGEMENT |
We thank Dr. Matti Jauhiainen, who kindly
performed high force re-ultracentrifugational isolation of
HDL3 and measured the CETP and PLTP activities in the
HDL3 samples.
| |
FOOTNOTES |
*
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: Wihuri Research
Institute, Kalliolinnantie 4, 01400 Helsinki, Finland. Fax:
358-9-637-476; E-mail: petri.kovanen@wihuri.fimnet.fi.
| |
ABBREVIATIONS |
The abbreviations used are:
HDL, high density
lipoprotein;
PAGE, polyacrylamide gel electrophoresis;
apo, apolipoprotein;
CETP, cholesterol ester transfer protein;
MALDI-TOF, matrix-assisted laser desorption/ionization time-of-flight;
MMP, matrix
metalloproteinase;
PLTP, phospholipid transfer protein;
CAPS, 3-(cyclohexylamino)-1-propanesulfonic acid.
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Copyright © 1999 by The American Society for Biochemistry and Molecular Biology, Inc.
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