Directory UMM :Data Elmu:jurnal:A:Atherosclerosis:Vol153.Issue1.Nov2000:

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Group-II phospholipase A

enhances oxidized low density

lipoprotein-induced macrophage growth through enhancement of

GM-CSF release

Kengo Kaneko, Masakazu Sakai *, Takeshi Matsumura, Takeshi Biwa,

Noboru Furukawa, Tetsuya Shirotani, Shinsuke Kiritoshi, Yoshichika Anami,

Kohji Matsuda, Takayuki Sasahara, Motoaki Shichiri

Department of Metabolic Medicine,Kumamoto Uni6ersity School of Medicine,1-1-1Honjo,Kumamoto860-8556,Japan

Received 26 July 1999; received in revised form 19 November 1999; accepted 19 January 2000

Abstract

Inflammatory process plays an important role in the development and progression of atherosclerotic lesions. Recently, group-II phospholipase A2(PLA2), an inflammatory mediator, was reported to exist in human atherosclerotic lesions and to enhance the

development of murine atherosclerotic lesions. Oxidized low density lipoprotein (Ox-LDL) stimulates the growth of several types of macrophages in vitro. Since proliferation of macrophages occurs in atherosclerotic lesions, it is possible to assume that the Ox-LDL-induced macrophage proliferation might be involved in the progression of atherosclerosis. In this study, the role of group-II PLA2 in the Ox-LDL-induced macrophage growth was investigated using thioglycollate-elicited mouse peritoneal

macrophages. Thioglycollate-elicited macrophages significantly expressed group-II PLA2and released it into the culture medium.

The Ox-LDL-induced thymidine incorporation into thioglycollate-elicited macrophages was three times higher than that into resident macrophages, whereas under the same conditions, granulocyte/macrophage colony-stimulating factor (GM-CSF) equally induced thymidine incorporation into both types of macrophages. Moreover, the Ox-LDL-induced GM-CSF release from thioglycollate-elicited macrophages was significantly higher than that from resident macrophages. In addition, the Ox-LDL-in-duced thymidine incorporation into macrophages obtained from human group-II PLA2transgenic mice and the GM-CSF release

from these cells were significantly higher than those from their negative littermates, and the Ox-LDL-induced thymidine incorporation into human group-II PLA2transgenic macrophages was significantly inhibited by a polyclonal anti-human group-II

PLA2 antibody. These results suggest that the expression of group-II PLA2in thioglycollate-elicited macrophages may play an

Keywords:Oxidized LDL; Macrophage growth; Atherosclerosis; Inflammation; Phospholipase A2; GM-CSF

www.elsevier.com/locate/atherosclerosis

1. Introduction

The presence of a massive cluster of macrophage-derived foam cells in the subendothelial spaces of

arter-ies is one of the characteristic features of the early stages of atherosclerotic lesions [1]. Macrophages take up chemically modified low density lipoproteins (LDL), such as oxidized LDL (Ox-LDL) and acetylated LDL (Ac-LDL), through the scavenger receptor pathways and become foam cells in vitro [2 – 4]. Macrophage-derived foam cells are believed to play an important role in the development and progression of atheroscle-rosis through the production of various cytokines and growth factors [1]. Previous studies have reported that macrophages and macrophage-derived foam cells pro-liferate in atherosclerotic lesions [5 – 7]. Recent studies Abbre6iations:GM-CSF, granulocyte/macrophage

colony-stimulat-ing factor; LDL, low density lipoprotein; Ox-LDL, oxidized LDL; PKC, protein kinase C; PLA2, phospholipase A2; WHHL, Watanabe

heritable hyperlipidemic; ELISA, enzyme-linked immunosorbent as-say.

* Corresponding author. Tel.: +81-96-3735169; fax: + 81-96-3668397.

E-mail address:[email protected] (M. Sakai).

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from the laboratory as well as by other investigators [8 – 17] have demonstrated that Ox-LDL could induce macrophage growth in vitro. Based on these findings, it was postulated that Ox-LDL might be involved in macrophage growth in vivo and linked to the progres-sion of atherosclerotic process.

One of the pathological and immunohistochemical features of atherosclerotic lesions is accumulation of inflammatory cells and cytokines [1]. Moreover, dexam-ethasone, an anti-inflammatory agent, is known to ex-hibit an anti-atherogenic effect in animal models of experimental atherosclerosis, such as Watanabe herita-ble hyperlipidemic (WHHL) rabbit [18], cholesterol-fed rabbit [19] and rat balloon angioplasty model [20]. Based on these studies, it seems reasonable to consider atherosclerosis as a chronic inflammatory disease, or that the inflammatory process plays an important role in the development and progression of atherosclerosis. Moreover, recent reports using human group-II phos-pholipase A2 (PLA2) transgenic mouse demonstrated that group-II PLA2, one of the inflammatory media-tors, played an enhancing role in the development of atherosclerotic lesions [21,22]. Thus, to further elucidate the pathophysiological significance of macrophage growth in atherosclerosis, it seems reasonable to investi-gate the growth promoting effect of Ox-LDL on inflam-matory macrophages, and the effect of group-II PLA2 on the Ox-LDL-induced macrophage growth. Here, the growth stimulating effects of Ox-LDL on the thiogly-collate-induced non-infectious inflammatory mouse peritoneal macrophages was examined. The results demonstrated that the responsiveness of thioglycollate-elicited macrophages to the growth-stimulating activity of Ox-LDL was significantly greater than that of resi-dent macrophages, and the expression of group-II PLA2 might play, at least in part, an enhancing role in the growth of thioglycollate-elicited macrophage through the enhancement of granulocyte/macrophage colony-stimulating factor (GM-CSF) release.

2. Methods 2.1. Chemicals

[methyl-3_{H]Thymidine and [1-}14_{C]oleic acid were} pur-chased from NEN Life Science (Boston, MA). A rabbit polyclonal anti-human group-II PLA2 antibody was purchased from Funakoshi (Tokyo, Japan). Other chemicals were of the highest grade available from commercial sources.

2.2. Cell culture

Peritoneal cells were collected from non-stimulated male C3H/He mice (25 – 30 g) (Japan SLC,

Hama-matsu, Japan) and commercially available human group-II PLA2transgenic mice and their negative litter-mates, C57BL/6J strain [23] (Taconic Farms, NY). Serum PLA2activity in transgenic mice was reported to be 8 – 10-fold greater than that in non-transgenic mice [23]. The preliminary experiment using RT-PCR showed the expression of human group-II PLA2 mRNA in PLA2-transgenic macrophages but not in their negative littermates. Kennedy et al. [24] demon-strated that some murine strain had natural null muta-tion for group-II PLA2, such as 129/Sv, B10.RIII and C57BL/6J, but C3H/He produced functional group-II PLA2. Thus, C3H/He mice were used in the present study for determination of the effect of group-II PLA2 on the macrophage growth. Thioglycollate-elicited macrophages were collected from C3H/He mice 5 days after intraperitoneal injection of 1.5 ml thioglycollate [25]. The collected peritoneal cells were suspended in RPMI 1640 medium (Nissui Seiyaku, Tokyo) supple-mented with 10% heat-inactivated fetal bovine serum (Life Technologies), streptomycin (0.1 mg/ml), and penicillin (100 U/ml) (medium A). After 90 min incuba-tion at 37°C, non-adherent cells were removed by tripli-cate washing with prewarmed medium A. After washing, cell numbers of resident and elicited macrophages were decreased to 70%. Macrophages were identified by the following features: (i) adherence to culture plates; (ii) morphological features resembling mononuclear cells after Giemsa staining; (iii) the capac-ity to take up carbon particles; and (iv) positive im-munohistochemistry with antibody for CD68.

2.3. Tritiated thymidine incorporation assay

Peritoneal cells were adjusted to 4×104_cells_/_{ml and} 1 ml of cell suspensions were dispersed in each well of 24-well tissue culture plates (15.5 mm in diameter, Corning Glass works, Corning NY) and incubated for 90 min at 37°C. Nonadherent cells were removed by washing three times with 1 ml of medium A. After washing, cell numbers of resident and elicited macrophages were counted by haemocytometer, and they were decreased to 70%. The macrophage mono-layers thus formed were cultured at 37°C with 1 ml of medium A in the presence of the lipoproteins to be tested. Eighteen hours before the termination of the experiments, 20 ml of 50 mCi/ml [3_{H]thymidine was} added to each well and incubated for 18 h at 37°C. After discarding the medium, each well was washed three times with 1 ml of PBS and the cells were lysed with 0.5 ml of 0.5 M NaOH by incubation on ice for 10 min. The cell lysates were neutralized with 0.25 ml of 1 M HCl, further precipitated with 0.25 ml of 40% trichloroacetic acid by incubation on ice for 20 min. The resulting trichloroacetic acid-insoluble material was collected on filters (Millipore PVDF filter; 0.45 mm in

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pore size) and washed three times with 1 ml of 99.5% ethanol. The filters were dried under air and their radioactivity was counted in a liquid scintillation coun-ter [13].

2.4. Cell-counting assay

Peritoneal cells were adjusted to 2×104_cells_/_{ml, and} 1 ml of cell suspension was dispersed in each well of 24-well tissue culture plates (16 mm in diameter, Fal-con) and incubated for 90 min at 37°C. Non-adherent cells were removed by triplicate washing with 1 ml of prewarmed medium A. The macrophage monolayers thus formed were cultured at 37°C in 1 ml of medium A, with or without the test lipoproteins. After incubation for 7 days, adherent cells in triplicate wells were lysed in 1% (w/v) Triton X-100, and the number of naphthol blue – black-stained nuclei was counted in a hemocytometer, as described previously [8].

2.5. Lipoproteins

Human LDL (d=1.019 – 1.063 g/ml) was isolated by sequential ultracentrifugation of plasma samples ob-tained from consented normolipidemic subjects after overnight fasting [26]. LDL was dialyzed against 0.15 M NaCl and 1 mM EDTA, pH 7.4. Ox-LDL was prepared by incubation of 0.1 mg/ml of LDL in PBS with 5 mM CuSO4 for 20 h at 37°C followed by the addition of 1 mM EDTA and cooling [27]. Acetyl-LDL was prepared by chemical modifica-tion of LDL with acetic anhydride as described previ-ously [28]. The level of endotoxin associated with these lipoproteins was B1 pg/mg protein as measured by a commercially available kit (Toxicolor system, Seika-gaku, Tokyo). Moreover, macrophage growth and vi-ability were not affected by endotoxin at a concentration below 1 ng/ml in the experimental sys-tem.

2.6. RT-PCR analysis for mouse group-II PLA2 Standard molecular biological techniques were used [29]. Macrophages (2×106 _{cells) were dispersed into} each well (3.5 cm in diameter, Nunc) and incubated for 90 min. After washing with medium A, macrophage monolayers thus formed in 2 ml of medium A for 6 h, and then total RNA was extracted with TRIzol (Life Technologies). The first strand cDNA synthesis con-taining 1 mg of total RNA was primed with oligo dT. Primers used for PCR amplification of group-II PLA2 and b-actin were designed on the basis of murine group-II PLA2 cDNA [30] and murine b-actin cDNA [31] sequences as follows: for group-II PLA2, forward primer; TTC TGG CAG TTC CAG AGG ATG G

(nucleotide 241 – 262 of murine group-II PLA2 coding sequence); reverse primer; AAG ACA CTC CCT AGA CAG CAA (nucleotide 678 – 709 of murine group-II PLA2 coding sequence) [30]; for b-actin, forward primer; GTG GGC CGC TCT AGG CAC CAA (nu-cleotide 25 – 45 of murine b-actin coding sequence); reverse primer; CTC TTT GAT GTC ACG CAC GAT TTC (nucleotide 541 – 564 of murine b-actin coding sequence) [31]. The cycling conditions in the GeneAmp 9600 System consisted of a first step of 94°C denaturation for 10 min, followed by 30 cycles of annealing at 54°C for 60 s, extension at 75°C for 90 s, and denaturation at 94°C for 30 s, with a final elongation step at 75°C for 10 min. Amplification products were analyzed by 1.5% agarose gel elec-trophoresis. To verify that amplification products were consistent with the reported sequences of murine group-II PLA2 and b-actin, they were ligated into pGEM-T (Promega, Madison, WI), transfected into Escherichia coli XL1-Blue and sequenced by using 373A DNA sequencer (Applied Biosystems, Foster City, CA).

2.7. Enzyme-linked immunosorbent assay (ELISA) for GM-CSF

Macrophages (5×106

cells) were dispersed into each well (10 cm in diameter, Falcon) and incubated for 90 min. After washing with medium A, macrophage monolayers thus formed were cultured in 15 ml of medium A with or without the lipoproteins to be tested for the indicated times, and then 300ml of the medium were collected. The concentration of GM-CSF protein was determined according to the instructions provided by the manufacturer of mouse GM-CSF-specific ELISA system (Amersham) using recombinant murine GM-CSF as a standard [13].

2.8. PLA2 acti6ity

PLA2 activity was determined using [1-14

C]oleate-la-beled E. coli phospholipid as a substrate, as described previously [32]. Assay mixtures contained 100 mM Tris – HCl (pH 7.4), 1 mM CaCl2, 2×10

8 _{cells of} [1-14_{C]oleate-labeled}_E_._coli _{and enzyme or conditioned} serum-free medium. Reaction mixtures were incubated for 1 h at 37°C. The reaction was terminated by the addition of 5 ml propane-2-ol/n-heptane/1 M H2SO4 (40/10/1, by vol.), followed by 2 ml heptane and 3 ml water. After vortex and phase separation, an aliquot (2.5 ml) of the upper phase was passed over a column of silic acid. Free [1-14_{C]oleate was quantitatively elute} with 1 ml ethyl acetate. Radioactivity was determined in a liquid scintillation counter. PLA2 activity was expressed as [1-14

C]oleate radioactivity released by indi-cated cell culture supernatant.

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2.9. Miscellaneous

Data were expressed as mean9S.D. Differences be-tween groups were compared for statistical significance using the Student’st-test. A probability value less than 5% was considered significant. The experimental proto-col was approved by the Human Ethics Review Com-mittee and the Ethics Review ComCom-mittee for Animal Experimentation of the institution.

3. Results

3.1. Thioglycollate-elicited macrophages express group-II PLA2

Various inflammatory bioactive molecules are secreted from cells in atherosclerotic lesions [1]. Among them, group-II PLA2 as a candidate for enhancing the Ox-LDL-induced macrophage growth was focused on for the following reasons: (i) previous studies reported the presence of group-II PLA2in human atherosclerotic lesions [33,34], which played an enhancing role in mouse atherosclerotic lesions [21,22]; and (ii) the pres-ence of group-II PLA2in peritoneal exudate induced by various stimuli [35 – 37]. RT-PCR analysis showed a faint band of mouse group-II PLA2 mRNA in resident

macrophages, whereas a clear band of mouse group-II PLA2 mRNA was present in thioglycollate-elicited macrophages (Fig. 1A). Next PLA2 activity in the macrophage conditioned medium was examined. Fig. 1B shows a significantly high PLA2 activity in the conditioned medium containing thioglycollate-elicited macrophages compared to that of resident macrophages. These results suggested that thioglycol-late-elicited macrophages produced a significantly higher amount of group-II PLA2into the medium than resident macrophages.

3.2. Ox-LDL stimulates growth of thioglycollate-elicited macrophages

The effects of Ox-LDL on the growth of mouse resident macrophages and thioglycollate-elicited macrophages were examined. Fig. 2A shows that thymidine incorporation into resident macrophages was induced by Ox-LDL in a dose-dependent manner, but neither by LDL nor acetyl-LDL. Fig. 2B shows that Ox-LDL also induced thymidine incorporation into thioglycollate-elicited macrophages, which was three times higher than that of resident macrophages (Fig. 2). As a control, thymidine incorporation induced by 1 nM of GM-CSF was almost equal in both types of macrophages (Fig. 2). Cell-counting assay also showed

Fig. 1. Polymerase chain reaction (PCR) analysis of mouse group-II phospholipase A2(PLA2) mRNA (A) and PLA2activity in medium (B). (A)

Mouse peritoneal macrophages (2×106_{cells) were seeded in 3.5 cm dish and incubated for 90 min. Non-adherent cells were removed by washing}

with medium A. The cell monolayers thus formed were incubated in 2 ml of medium A alone for 1 h. After incubation, total RNA was extracted from each dish with TRIzol. The expression of mRNA for mouse group-II PLA2(upper panel) orb-actin (lower panel) was evaluated by RT-PCR

as described in Section 2. (B) Mouse peritoneal resident macrophages () or thioglycollate-elicited macrophages ( ) (1×107_{cells) were seeded}

in 10 cm dish and incubated for 90 min. After washing with medium A, the cell monolayers thus formed were incubated at 37°C for 18 h in 10 ml of RPMI 1640 with 3% bovine serum albumin (BSA). After incubation, the conditioned medium was collected and PLA2 activity was

determined as described under Section 2. After washing with PBS, cells were lysed with 0.1 N NaOH and protein contents were determined using BCA reagent (Pierce). Data represent the mean9S.D. of three separate experiments. *PB0.01 compared to medium alone by Student’st-test.

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Fig. 2. Oxidized low density lipoprotein (Ox-LDL)-induced growth of resident macrophages (A) and thioglycollate-elicited macrophages (B). Mouse peritoneal macrophages (4×104_{cells) were dispersed in}

each well, and incubated for 90 min. Non-adherent cells were re-moved by washing with medium A. The cell monolayers thus formed were incubated for 6 days in 1 ml of medium A with the indicated concentrations of Ox-LDL (), acetyl-LDL () or LDL (). As a control experiment, cells were incubated with 1 nM of recombinant granulocyte/macrophage colony-stimulating factor (GM-CSF). Eigh-teen hours before the termination of experiments, cells were chased with [3_{H]thymidine, harvested and radioactivity was determined as}

described under Section 2. Data represent the mean9S.D. of four separate experiments. *PB0.01 compared to medium alone, †PB

0.005 compared to medium alone by Student’st-test.

Fig. 3. Effect of oxidized low density lipoprotein (Ox-LDL) on [3_{H]thymidine incorporation into macrophages derived from human}

group-II phospholipase A2 (PLA2) transgenic mice. Mouse resident

peritoneal macrophages from human group-II PLA2transgenic mice

or their negative littermates (4×104_{cells) were dispersed in 24 well}

plates, and incubated for 90 min. After washing, cell monolayers thus formed were incubated at 37°C for 6 days in 1 ml of medium A with the indicated concentrations of Ox-LDL (), acetyl-LDL (), LDL () or 1 nM of recombinant mouse granulocyte/macrophage colony-stimulating factor (GM-CSF) as a control. Thymidine incorporation was determined as described in Section 2. Data represent the mean9

SD of three separate experiments. *PB0.01 compared to medium alone by Student’st-test.

ulating activity of Ox-LDL was significantly greater than that of resident macrophages.

3.3. Group-II PLA2 enhances macrophage growth To determine the role of group-II PLA2 in the LDL-induced macrophage growth, the effect of Ox-LDL on the growth of macrophages obtained from human group-II PLA2 transgenic mice was examined. Fig. 3 shows that the Ox-LDL-induced thymidine in-that the number of resident macrophages increased 1.8

times by Ox-LDL compared to non-loaded resident macrophages, whereas the number of thioglycollate-elicited macrophages was significantly increased 2.3 times by Ox-LDL (Table 1). These results demonstrated that the growth of thioglycollate-elicited macrophages was also induced by Ox-LDL and the responsiveness of thioglycollate-elicited macrophages to the growth-stim-Table 1

Ox-LDL-induced growth of mouse resident and thioglycollate-elicited inflammatory macrophagesa

Macrophages Lipoproteins Cell number (×10−4_/well) _{% Medium alone}

100 Resident macrophages Medium alone 1.490.2

100 1.490.3

LDL

107 1.590.3

Acetyl-LDL

179

Ox-LDL 2.590.2*

GM-CSF 2.890.4* 200

Medium alone

Elicited macrophages 1.590.2 100

107

LDL 1.690.4

Acetyl-LDL 1.890.3 127

227 3.490.2**

Ox-LDL

3.090.3**

GM-CSF 200

a_{Peritoneal macrophages (2×10}4_{cells) were dispersed into culture plates, and incubated for 90 min. After incubation, non-adherent cells were}

removed by triplicate washing with medium A. At the start of experiment, cell numbers of resident and elicited macrophages were 1.4 and 1.5×104

cells/well, respectively. Macrophage monolayers thus formed were incubated for 7 days in 1 ml of medium A with 20mg/ml of lipoproteins or 1 nM of GM-CSF as a control. After incubation, counting of solubilized nuclei was performed as described under Section 2. Data are expressed as mean9S.D. of quadriplicate counts. LDL, low density lipoprotein; Ox-LDL, oxidized low density lipoprotein; GM-CSF, granulocyte/ macrophage colony-stimulating factor.

*PB0.01, compared to medium alone.

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corporation into macrophages from human group-II PLA2 transgenic mice was twice that from their nega-tive littermates. Moreover, the Ox-LDL-induced thymidine incorporation into macrophages from human group-II PLA2 transgenic mice was significantly but partially inhibited by 50% by a polyclonal anti-human group-II PLA2 antibody as compared to that by non-immune IgG (Fig. 4). These results suggested that group-II PLA2 might enhance, at least in part, the Ox-LDL-induced macrophage growth.

3.4. Ox-LDL augments GM-CSF release

It has recently been reported that GM-CSF played a priming role in the Ox-LDL-induced macrophage growth [13]. Thus, the production of GM-CSF from thioglycollate-elicited macrophages was next examined. When resident macrophages were incubated with medium alone for 6 h, GM-CSF was released at con-centration of 8.2 fM/mg protein (Table 2). Ox-LDL significantly enhanced the GM-CSF release from resi-dent macrophages into the medium in a dose-depenresi-dent manner with a maximal concentration of 30.2 fM/mg

protein at 40mg/ml of Ox-LDL (Table 2). On the other hand, when thioglycollate-elicited macrophages were incubated with medium alone, the concentration of GM-CSF in the medium was 7.8 fM/mg protein (Table 2). However, the GM-CSF release from thioglycollate-elicited macrophages was increased by Ox-LDL with maximal concentration of 40.5 fM/mg protein, which was significantly higher than that from resident macrophages induced by Ox-LDL (Table 2). In con-trast, LDL or acetyl-LDL could not enhance the GM-CSF release from both types of macrophages (Table 2). Combined with the results of macrophage growth (Fig. 2) and PLA2 activity (Fig. 1), these results suggested that PLA2might enhance the effect of Ox-LDL on the GM-CSF release as well as macrophage growth. To confirm this conclusion, the effect of Ox-LDL on the GM-CSF release from human group-II PLA2 trans-genic macrophages was examined. As shown in Table 3, the Ox-LDL-induced GM-CSF release from macrophages obtained from wild type littermates was 2.1 times greater than that from wild cells which were incubated with medium alone. Consistent with macrophage growth (Fig. 4), the Ox-LDL-induced GM-CSF release from human group-II PLA2 trans-genic macrophages was significantly greater than that from wild macrophages (Table 3). These results sug-gested that group-II PLA2 enhances GM-CSF release from thioglycollate-elicited macrophages, thereby en-hancing the Ox-LDL-induced macrophage growth.

4. Discussion

Recent studies from the laboratory as well as by others have demonstrated that Ox-LDL could induce the growth of several types of macrophages in vitro [8 – 17], whereas the importance of in situ macrophage growth during the development of atherosclerotic le-sions is still unknown. It is possible to assume that the Ox-LDL-induced macrophage growth is involved in the development and progression of atherosclerotic lesions because: (i) macrophages and macrophage-derived foam cells are believed to play an essential role in the development and progression of atherosclerosis via pro-duction of various active molecules [1]; and (ii) prolifer-ation of macrophages has been observed in atherosclerotic lesions [2 – 4].

Recent immunohistochemical and pathological stud-ies suggested that the inflammatory process was in-volved in the development and progression of atherosclerosis [1,18 – 20]. Moreover, recent reports us-ing human group-II PLA2 transgenic mouse demon-strated that group-II PLA2, an inflammatory mediator, played an enhancing role in the development of atherosclerotic lesions [21,22]. Thus, it seems reasonable to investigate the growth promoting effects of Ox-LDL Fig. 4. Effect of an anti-human group-II phospholipase A2 (PLA2)

antibody on oxidized low density lipoprotein (Ox-LDL)-induced [3_{H]thymidine incorporation into macrophages derived from human}

group-II PLA2 transgenic mice. Mouse resident peritoneal

macrophages from human group-II PLA2 transgenic mice (4×104

cells) were dispersed in 24 well plates, and incubated for 90 min. After washing with medium A, cell monolayers thus formed were incubated at 37°C for 6 days in 1 ml of medium A with 20mg/ml Ox-LDL in the presence or absence of 10 mg/ml of anti-human group-II PLA2

antibody or non-immune IgG. Thymidine incorporation was deter-mined as described in Section 2. Data represent the mean9S.D. of three separate experiments. *PB0.01 as compared to medium alone, †PB0.05 as compared to Ox-LDL loaded cells by Student’st-test.

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Table 2

Ox-LDL-induced GM-CSF release from macrophagesa

GM-CSF (fmol/mg protein)

Macrophages Lipoproteins (mg/ml) % Medium alone

Medium alone

Resident macrophages 8.291.1 100

25.293.5*

Ox-LDL (20) 307

30.292.1* 368

Ox-LDL (40)

10.692.0

Ac-LDL (20) 129

LDL (20) 9.891.3 120

7.891.2

Elicited macrophages Medium alone 100

34.492.0** 441

Ox-LDL (20)

40.593.1**

Ox-LDL (40) 519

Ac-LDL (20) 9.192.7 117

7.791.2 99

LDL (20)

a_{Peritoneal macrophages (2×10}6_{cells) were dispersed into culture plates, and incubated for 90 min. After incubation, non-adherent cells were}

removed by triplicate washing with medium A. Macrophage monolayers thus formed were incubated for 6 h in 1 ml of medium A with the indicated concentrations of lipoproteins. After incubation, culture medium were taken and the levels of GM-CSF was determined by ELISA as described under Section 2. Contents of cellular proteins were determined using BCA reagent (Pierce). Data are expressed as mean9S.D. of quadriplicate. Ox-LDL, oxidized low density lipoprotein; GM-CSF, granulocyte/macrophage colony-stimulating factor.

*PB0.01, compared to non-loaded resident macrophages.

**PB0.01, compared to non-loaded elicited macrophages by Student’st-test.

on inflammatory macrophages. Jutila and Banks [38] reported that the thymidine incorporation into non-stimulated thioglycollate-elicited inflammatory macrophage was greater than that into non-stimulated resident macrophages, whereas it was unclear whether Ox-LDL could induce the growth of thioglycollate-elic-ited macrophages. The present study demonstrated that Ox-LDL induced the growth of thioglycollate-elicited macrophages, which was significantly higher than the Ox-LDL-induced growth of resident macrophages (Fig. 2 and Table 1).

The results showed that the Ox-LDL-induced growth of thioglycollate-elicited macrophages was significantly greater than that of resident macrophages (Fig. 2 and Table 1), and the expression of group-II PLA2 might play, at least in part, an enhancing role in this phe-nomenon (Fig. 1). This conclusion was supported by the following findings: (i) the Ox-LDL-induced thymidine incorporation into macrophages from human group-II PLA2 transgenic mice was significantly higher than that from their negative littermates (Fig. 3); and (ii) such incorporation was significantly but partially inhibited by a polyclonal anti-human group-II PLA2 antibody (Fig. 4). The presence of group-II PLA2 has been observed in local and systemic inflammatory con-ditions, such as peritonitis, rheumatoid arthritis and septic shock [39,40]. Group-II PLA2plays an enhancing role in inflammation via production of lysophospho-lipids and release of arachidonic acid, a precursor of prostaglandins [39]. Recent immunohistochemical stud-ies demonstrated that group-II PLA2 was also ex-pressed in atherosclerotic lesions [32,33], and its expression was correlated with the degree of atheroscle-rosis [41]. This enzyme is mainly associated with vascu-lar smooth muscle cells in the normal media and intima

of human atherosclerotic arterial wall, which is consis-tent with the results demonstrating the source of group-II PLA2 in other human tissues [42,43]. Moreover, group-II PLA2 in human atherosclerotic lesions is known to be associated with macrophages and lipid core lesions [44]. Interestingly, in addition to atheroscle-rotic lesions, macrophage proliferation has also been observed in tumors and inflamed lung [45 – 48], where the expression of group-II PLA2has been reported [40]. Thus, it is possible that group-II PLA2 may enhance macrophage proliferation by certain stimuli in various tissues. In the present study, the enhancing effect of group-II PLA2 on the Ox-LDL-induced macrophage growth has been focused on. It should be noted, how-ever, that various active molecules are expressed in atherosclerotic lesions apart from group-II PLA2 [1]. Thus, further studies are necessary to examine whether other active molecules enhance the Ox-LDL-induced growth of thioglycollate-elicited macrophages.

Group-I PLA2 is another type of secretary PLA2 derived mainly from pancreatic juice [40]. This enzyme is known to exhibit a growth stimulating activity for fibroblasts through its specific receptor [49]. However, it remains unclear whether group-II PLA2 directly in-duces cell growth. Kurizaki et al. [50] has reported that group-II PLA2 induced fibroblast growth, although the exact mechanism of this process remains unknown at present. In the present study, following incubation of macrophages with medium alone, macrophage growth did not occur in thioglycollate-elicited macrophages and human group-II PLA2-transgenic macrophages which produced a significant amount of group-II PLA2 (Figs. 2 and 3). Moreover, the preliminary experiments showed that PLA2 alone did not induce resident macrophage growth. These findings suggested that

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group-II PLA2 did not induce macrophage growth di-rectly, and that it exhibited a growth enhancing activity for macrophages via phospholipid metabolites, such as lysophospholipids, arachidonate itself or its metabo-lites. Since it was previously reported that receptor-me-diated endocytosis of lysophosphatidylcholine in Ox-LDL through the scavenger receptors played an important role in the Ox-LDL-induced macrophage growth [8], it was possible that PLA2 might increase in lysophosphatidylcholine content in Ox-LDL, thereby enhancing the Ox-LDL-induced macrophage growth. However, a significant change of lysophosphatidyl-choline content in the conditioned medium could not be detected, in spite of an increase in PLA2 activity. The exact reason of these apparently inconsistent results remains unclear, but it is possible to assume that during incubation with macrophages, lysophosphatidylcholine hydrolyzed from phosphatidylcholine by PLA2 may be further reduced by other enzymes to glycerolphosphate or other metabolites, or may receive re-acylation to phosphatidylcholine in the cell culture system. There-fore, the change of lysophosphatidylcholine contents in the conditioned medium after incubation with macrophages might not be detected. On the other hand, Martens et al. [16] recently demonstrated that oxidized arachidonate might modify apoB and then induce macrophage growth. Moreover, it was reported that free fatty acids, another part of phosphatidylcholine metabolite by PLA2, in LDL were oxidized by cells and enhanced further oxidation of LDL [51]. These findings suggested that arachidonate or its oxidatively modified metabolite(s) might enhance the Ox-LDL-induced growth of thioglycollate-elicited macrophages. How-ever, the precise mechanisms of action are still un-known at present and further studies are needed to elucidate PLA2-mediated enhancement of the Ox-LDL-induced macrophage growth.

In the present study, the Ox-LDL-induced thioglycol-late-elicited macrophage growth, PLA2 activity in con-ditioned medium and GM-CSF release from these cells

were all significantly greater than those of resident macrophages (Figs. 1 and 2, and Table 2). Moreover, the Ox-LDL-induced growth of human group-II PLA2 transgenic macrophages and the GM-CSF release from these cells were both significantly greater than those from wild macrophages (Fig. 3 and Table 3). Further-more, both elicited and resident macrophages were equal in their response to the growth-promoting activ-ity of recombinant GM-CSF (Fig. 2). These results suggested that group-II PLA2 promotes the Ox-LDL-induced macrophage growth through enhancement of the GM-CSF release. A recent study demonstrated that dexamethasone inhibited the Ox-LDL-induced macrophage growth which was explained by the inhibi-tion of the GM-CSF expression [52]. Moreover, dexam-ethasone was reported to inhibit the expression of group-II PLA2 in rat macrophages [53]. These findings also supported the conclusion that group-II PLA2 might enhance the expression of GM-CSF. However, the enhancing mechanism of group-II PLA2 for the GM-CSF release from macrophages remains unclear at present. It was previously demonstrated that a rise in intracellular calcium and a subsequent increase in PKC activity were involved in the Ox-LDL-induced GM-CSF release and the subsequent macrophage growth [14]. Moreover, Martens et al. [15] recently reported that phosphatidylinositol 3-kinase (PI3K) was involved in the Ox-LDL-induced macrophage growth. Further studies are necessary to elucidate the mechanism of the group-II PLA2-mediated enhancement of GM-CSF re-lease and the subsequent macrophage growth.

It was previously demonstrated that PLA2-treated acetyl-LDL significantly induced macrophage growth [8]. However, when elicited-macrophages or human PLA2-transgenic macrophages, which released a signifi-cant amount of group-II PLA2, were incubated with acetyl-LDL, macrophage growth did not observed (Figs. 2 and 3). These results were apparently inconsis-tent. When macrophages were incubated with acetyl-LDL, acetyl-LDL bound to the scavenger receptors and Table 3

Ox-LDL-induced GM-CSF release from human group-II PLA2 transgenic macrophagesa

Macrophages Ox-LDL (mg/ml) GM-CSF (fmol/mg protein) % Medium alone

0 7.891.4 100

Wild macrophages

40 16.592.8* 212

5.691.3 100

PLA2-transgenic macrophages 0

20.992.2** 373

a_{Peritoneal macrophages (2×10}6_{cells) were dispersed into culture plates, and incubated for 90 min. After incubation non-adherent cells were}

removed by triplicate washing with medium A. Macrophage monolayers thus formed were incubated for 6 h in 1 ml of medium A with indicated concentrations of lipoproteins. After incubation, culture medium were taken and the levels of GM-CSF was determined by ELISA as described under Section 2. Contents of cellular proteins were determined using BCA reagent (Pierce). Data are expressed as mean9S.D. of triplicate. Ox-LDL, oxidized low density lipoprotein; GM-CSF, granulocyte/macrophage colony-stimulating factor; PLA2, phospholipase A2.

*PB0.01, compared to non-loaded wild macrophages.

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was endocytosed by macrophages immediately. More-over, since the medium used in the present study con-tained 10% fetal calf serum (FCS), a large amount of phosphatidylcholine might prevent hydrolysis of phos-phatidylcholine in acetyl-LDL. Thus, it is possible to assume that if a small amount of phosphatidylcholine would be hydrolyzed to lysophosphatidylcholine in ace-tyl-LDL by the action of PLA2, it might not be enough for the induction of macrophage growth.

Based on the finding that Ox-LDL significantly in-duced the growth of peritoneal cells obtained from M-CSF and GM-CSF double knockout mouse, Hamil-ton et al. [17] proposed that the GM-CSF release from macrophages was not required for the Ox-LDL-induced macrophage growth. Since both M-CSF and GM-CSF are well known growth factors regulating the differenti-ation and the proliferdifferenti-ation of monocytes/macrophages, it is possible to assume that peritoneal cells from double knockout mice could represent immature macrophages or poorly differentiated monocytic cells. In fact, M-CSF knockout mice are known to develop osteopetrosis which is caused by immaturation of osteoclast, a resi-dent macrophage [54,55]. Moreover, it is reported that Ox-LDL is able to induce the differentiation of mono-cytes into macrophages [56]. These findings suggested that the effect of Ox-LDL on immature macrophages might differ in quality from that on mature macrophages.

Acknowledgements

This work was supported in part by a grant form Ono Medical Research Foundation.

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described under Section 2. Data represent the mean9S.D. of four separate experiments. *PB0.01 compared to medium alone, †PB

0.005 compared to medium alone by Student’st-test.

Fig. 3. Effect of oxidized low density lipoprotein (Ox-LDL) on [3_{H]thymidine incorporation into macrophages derived from human}

group-II phospholipase A2 (PLA2) transgenic mice. Mouse resident

peritoneal macrophages from human group-II PLA2transgenic mice

or their negative littermates (4×104_{cells) were dispersed in 24 well}

SD of three separate experiments. *PB0.01 compared to medium alone by Student’st-test.

ulating activity of Ox-LDL was significantly greater

than that of resident macrophages.

3 .

Group

-

II PLA

enhances macrophage growth

To determine the role of group-II PLA2

in the

LDL-induced macrophage growth, the effect of

Ox-LDL on the growth of macrophages obtained from

human group-II PLA2

transgenic mice was examined.

Fig. 3 shows that the Ox-LDL-induced thymidine

in-that the number of resident macrophages increased 1.8

times by Ox-LDL compared to non-loaded resident

macrophages, whereas the number of

thioglycollate-elicited macrophages was significantly increased 2.3

times by Ox-LDL (Table 1). These results demonstrated

that the growth of thioglycollate-elicited macrophages

was also induced by Ox-LDL and the responsiveness of

thioglycollate-elicited macrophages to the

growth-stim-Table 1

Ox-LDL-induced growth of mouse resident and thioglycollate-elicited inflammatory macrophagesa

Macrophages Lipoproteins Cell number (×10−4_/well) _{% Medium alone}

100 Resident macrophages Medium alone 1.490.2

100 1.490.3

LDL

107 1.590.3

Acetyl-LDL

179

Ox-LDL 2.590.2*

GM-CSF 2.890.4* 200

Medium alone

Elicited macrophages 1.590.2 100

107

LDL 1.690.4

Acetyl-LDL 1.890.3 127

227 3.490.2**

Ox-LDL

3.090.3**

GM-CSF 200

a_{Peritoneal macrophages (2×10}4_{cells) were dispersed into culture plates, and incubated for 90 min. After incubation, non-adherent cells were}

removed by triplicate washing with medium A. At the start of experiment, cell numbers of resident and elicited macrophages were 1.4 and 1.5×104

*PB0.01, compared to medium alone.

(2)

corporation into macrophages from human group-II

PLA

transgenic mice was twice that from their

nega-tive

littermates.

Moreover,

the

Ox-LDL-induced

thymidine incorporation into macrophages from human

group-II PLA2

transgenic mice was significantly but

partially inhibited by 50% by a polyclonal anti-human

group-II PLA2

antibody as compared to that by

non-immune IgG (Fig. 4). These results suggested that

group-II PLA2

might enhance, at least in part, the

Ox-LDL-induced macrophage growth.

3 .

4 .

Ox

-

LDL augments GM

-

CSF release

It has recently been reported that GM-CSF played a

priming role in the Ox-LDL-induced macrophage

growth [13]. Thus, the production of GM-CSF from

thioglycollate-elicited macrophages was next examined.

When resident macrophages were incubated with

medium alone for 6 h, GM-CSF was released at

con-centration of 8.2 fM

/

mg protein (Table 2). Ox-LDL

significantly enhanced the GM-CSF release from

resi-dent macrophages into the medium in a dose-depenresi-dent

manner with a maximal concentration of 30.2 fM

/

mg

protein at 40

mg

/

ml of Ox-LDL (Table 2). On the other

hand, when thioglycollate-elicited macrophages were

incubated with medium alone, the concentration of

GM-CSF in the medium was 7.8 fM

/

mg protein (Table

2). However, the GM-CSF release from

thioglycollate-elicited macrophages was increased by Ox-LDL with

maximal concentration of 40.5 fM

/

mg protein, which

was significantly higher than that from resident

macrophages induced by Ox-LDL (Table 2). In

con-trast, LDL or acetyl-LDL could not enhance the

GM-CSF release from both types of macrophages (Table 2).

Combined with the results of macrophage growth (Fig.

2) and PLA2

activity (Fig. 1), these results suggested

that PLA2

might enhance the effect of Ox-LDL on the

GM-CSF release as well as macrophage growth. To

confirm this conclusion, the effect of Ox-LDL on the

GM-CSF release from human group-II PLA

trans-genic macrophages was examined. As shown in Table 3,

the

Ox-LDL-induced

GM-CSF

release

from

macrophages obtained from wild type littermates was

2.1 times greater than that from wild cells which were

incubated

with

medium

alone.

Consistent

with

macrophage growth (Fig. 4), the Ox-LDL-induced

GM-CSF release from human group-II PLA2

trans-genic macrophages was significantly greater than that

from wild macrophages (Table 3). These results

sug-gested that group-II PLA2

enhances GM-CSF release

from thioglycollate-elicited macrophages, thereby

en-hancing the Ox-LDL-induced macrophage growth.

4. Discussion

Recent studies from the laboratory as well as by

others have demonstrated that Ox-LDL could induce

the growth of several types of macrophages in vitro

[8 – 17], whereas the importance of in situ macrophage

growth during the development of atherosclerotic

le-sions is still unknown. It is possible to assume that the

Ox-LDL-induced macrophage growth is involved in the

development and progression of atherosclerotic lesions

because: (i) macrophages and macrophage-derived

foam cells are believed to play an essential role in the

development and progression of atherosclerosis via

pro-duction of various active molecules [1]; and (ii)

prolifer-ation

of

macrophages

has

been

observed

in

atherosclerotic lesions [2 – 4].

Recent immunohistochemical and pathological

stud-ies suggested that the inflammatory process was

in-volved

in

the

development

and

progression

of

atherosclerosis [1,18 – 20]. Moreover, recent reports

us-ing human group-II PLA2

transgenic mouse

demon-strated that group-II PLA2, an inflammatory mediator,

played an enhancing role in the development of

atherosclerotic lesions [21,22]. Thus, it seems reasonable

to investigate the growth promoting effects of Ox-LDL

Fig. 4. Effect of an anti-human group-II phospholipase A2 (PLA2)

antibody on oxidized low density lipoprotein (Ox-LDL)-induced [3_{H]thymidine incorporation into macrophages derived from human}

group-II PLA2 transgenic mice. Mouse resident peritoneal

macrophages from human group-II PLA2 transgenic mice (4×104

(3)

Table 2

Ox-LDL-induced GM-CSF release from macrophagesa

GM-CSF (fmol/mg protein)

Macrophages Lipoproteins (mg/ml) % Medium alone

Medium alone

Resident macrophages 8.291.1 100

25.293.5*

Ox-LDL (20) 307

30.292.1* 368

Ox-LDL (40)

10.692.0

Ac-LDL (20) 129

LDL (20) 9.891.3 120

7.891.2

Elicited macrophages Medium alone 100

34.492.0** 441

Ox-LDL (20)

40.593.1**

Ox-LDL (40) 519

Ac-LDL (20) 9.192.7 117

7.791.2 99

LDL (20)

a_{Peritoneal macrophages (2×10}6_{cells) were dispersed into culture plates, and incubated for 90 min. After incubation, non-adherent cells were}

*PB0.01, compared to non-loaded resident macrophages.

**PB0.01, compared to non-loaded elicited macrophages by Student’st-test.

on inflammatory macrophages. Jutila and Banks [38]

reported that the thymidine incorporation into

non-stimulated

thioglycollate-elicited

inflammatory

macrophage was greater than that into non-stimulated

resident macrophages, whereas it was unclear whether

Ox-LDL could induce the growth of

thioglycollate-elic-ited macrophages. The present study demonstrated that

Ox-LDL induced the growth of thioglycollate-elicited

macrophages, which was significantly higher than the

Ox-LDL-induced growth of resident macrophages (Fig.

2 and Table 1).

The results showed that the Ox-LDL-induced growth

of thioglycollate-elicited macrophages was significantly

greater than that of resident macrophages (Fig. 2 and

Table 1), and the expression of group-II PLA2

might

play, at least in part, an enhancing role in this

phe-nomenon (Fig. 1). This conclusion was supported by

the

following

findings:

(i)

the

Ox-LDL-induced

thymidine incorporation into macrophages from human

group-II PLA

transgenic mice was significantly higher

than that from their negative littermates (Fig. 3); and

(ii) such incorporation was significantly but partially

inhibited by a polyclonal anti-human group-II PLA2

antibody (Fig. 4). The presence of group-II PLA2

has

been observed in local and systemic inflammatory

con-ditions, such as peritonitis, rheumatoid arthritis and

septic shock [39,40]. Group-II PLA

plays an enhancing

role in inflammation via production of

lysophospho-lipids and release of arachidonic acid, a precursor of

prostaglandins [39]. Recent immunohistochemical

stud-ies demonstrated that group-II PLA2

was also

ex-pressed in atherosclerotic lesions [32,33], and its

expression was correlated with the degree of

atheroscle-rosis [41]. This enzyme is mainly associated with

vascu-lar smooth muscle cells in the normal media and intima

of human atherosclerotic arterial wall, which is

consis-tent with the results demonstrating the source of

group-II PLA2

in other human tissues [42,43]. Moreover,

group-II PLA2

in human atherosclerotic lesions is

known to be associated with macrophages and lipid

core lesions [44]. Interestingly, in addition to

atheroscle-rotic lesions, macrophage proliferation has also been

observed in tumors and inflamed lung [45 – 48], where

the expression of group-II PLA2

has been reported [40].

Thus, it is possible that group-II PLA2

may enhance

macrophage proliferation by certain stimuli in various

tissues. In the present study, the enhancing effect of

group-II PLA

on the Ox-LDL-induced macrophage

growth has been focused on. It should be noted,

how-ever, that various active molecules are expressed in

atherosclerotic lesions apart from group-II PLA2

[1].

Thus, further studies are necessary to examine whether

other active molecules enhance the Ox-LDL-induced

growth of thioglycollate-elicited macrophages.

Group-I PLA

is another type of secretary PLA

derived mainly from pancreatic juice [40]. This enzyme

is known to exhibit a growth stimulating activity for

fibroblasts through its specific receptor [49]. However, it

remains unclear whether group-II PLA2

directly

in-duces cell growth. Kurizaki et al. [50] has reported that

group-II PLA2

induced fibroblast growth, although the

exact mechanism of this process remains unknown at

present. In the present study, following incubation of

macrophages with medium alone, macrophage growth

did not occur in thioglycollate-elicited macrophages

and human group-II PLA2-transgenic macrophages

which produced a significant amount of group-II PLA2

(Figs. 2 and 3). Moreover, the preliminary experiments

showed that PLA

alone did not induce resident

macrophage growth. These findings suggested that

(4)

group-II PLA2

did not induce macrophage growth

di-rectly, and that it exhibited a growth enhancing activity

for macrophages via phospholipid metabolites, such as

lysophospholipids, arachidonate itself or its

metabo-lites. Since it was previously reported that

receptor-me-diated

endocytosis

of

lysophosphatidylcholine

in

Ox-LDL through the scavenger receptors played an

important role in the Ox-LDL-induced macrophage

growth [8], it was possible that PLA2

might increase in

lysophosphatidylcholine content in Ox-LDL, thereby

enhancing the Ox-LDL-induced macrophage growth.

However, a significant change of

lysophosphatidyl-choline content in the conditioned medium could not be

detected, in spite of an increase in PLA2

activity. The

exact reason of these apparently inconsistent results

remains unclear, but it is possible to assume that during

incubation with macrophages, lysophosphatidylcholine

hydrolyzed from phosphatidylcholine by PLA2

may be

further reduced by other enzymes to glycerolphosphate

or other metabolites, or may receive re-acylation to

phosphatidylcholine in the cell culture system.

There-fore, the change of lysophosphatidylcholine contents in

the

conditioned

medium

after

incubation

with

macrophages might not be detected. On the other hand,

Martens et al. [16] recently demonstrated that oxidized

arachidonate might modify apoB and then induce

macrophage growth. Moreover, it was reported that

free fatty acids, another part of phosphatidylcholine

metabolite by PLA2, in LDL were oxidized by cells and

enhanced further oxidation of LDL [51]. These findings

suggested that arachidonate or its oxidatively modified

metabolite(s) might enhance the Ox-LDL-induced

growth of thioglycollate-elicited macrophages.

How-ever, the precise mechanisms of action are still

un-known at present and further studies are needed to

elucidate PLA2-mediated enhancement of the

Ox-LDL-induced macrophage growth.

In the present study, the Ox-LDL-induced

thioglycol-late-elicited macrophage growth, PLA2

activity in

con-ditioned medium and GM-CSF release from these cells

were all significantly greater than those of resident

macrophages (Figs. 1 and 2, and Table 2). Moreover,

the Ox-LDL-induced growth of human group-II PLA2

transgenic macrophages and the GM-CSF release from

these cells were both significantly greater than those

from wild macrophages (Fig. 3 and Table 3).

Further-more, both elicited and resident macrophages were

equal in their response to the growth-promoting

activ-ity of recombinant GM-CSF (Fig. 2). These results

suggested that group-II PLA2

promotes the

Ox-LDL-induced macrophage growth through enhancement of

the GM-CSF release. A recent study demonstrated that

dexamethasone

inhibited

the

Ox-LDL-induced

macrophage growth which was explained by the

inhibi-tion of the GM-CSF expression [52]. Moreover,

dexam-ethasone was reported to inhibit the expression of

group-II PLA

in rat macrophages [53]. These findings

also supported the conclusion that group-II PLA

might enhance the expression of GM-CSF. However,

the enhancing mechanism of group-II PLA2

for the

GM-CSF release from macrophages remains unclear at

present. It was previously demonstrated that a rise in

intracellular calcium and a subsequent increase in PKC

activity were involved in the Ox-LDL-induced

GM-CSF release and the subsequent macrophage growth

[14]. Moreover, Martens et al. [15] recently reported

that phosphatidylinositol 3-kinase (PI3K) was involved

in the Ox-LDL-induced macrophage growth. Further

studies are necessary to elucidate the mechanism of the

group-II PLA2-mediated enhancement of GM-CSF

re-lease and the subsequent macrophage growth.

It was previously demonstrated that PLA2-treated

acetyl-LDL significantly induced macrophage growth

[8]. However, when elicited-macrophages or human

PLA2-transgenic macrophages, which released a

signifi-cant amount of group-II PLA2, were incubated with

acetyl-LDL, macrophage growth did not observed

(Figs. 2 and 3). These results were apparently

inconsis-tent. When macrophages were incubated with

acetyl-LDL, acetyl-LDL bound to the scavenger receptors and

Table 3

Ox-LDL-induced GM-CSF release from human group-II PLA2 transgenic macrophagesa

Macrophages Ox-LDL (mg/ml) GM-CSF (fmol/mg protein) % Medium alone

0 7.891.4 100

Wild macrophages

40 16.592.8* 212

5.691.3 100

PLA2-transgenic macrophages 0

20.992.2** 373

a_{Peritoneal macrophages (2×10}6_{cells) were dispersed into culture plates, and incubated for 90 min. After incubation non-adherent cells were}

*PB0.01, compared to non-loaded wild macrophages.

(5)

was endocytosed by macrophages immediately.

More-over, since the medium used in the present study

con-tained 10% fetal calf serum (FCS), a large amount of

phosphatidylcholine might prevent hydrolysis of

phos-phatidylcholine in acetyl-LDL. Thus, it is possible to

assume that if a small amount of phosphatidylcholine

would be hydrolyzed to lysophosphatidylcholine in

ace-tyl-LDL by the action of PLA2, it might not be enough

for the induction of macrophage growth.

Based on the finding that Ox-LDL significantly

in-duced the growth of peritoneal cells obtained from

M-CSF and GM-CSF double knockout mouse,

Hamil-ton et al. [17] proposed that the GM-CSF release from

macrophages was not required for the Ox-LDL-induced

macrophage growth. Since both M-CSF and GM-CSF

are well known growth factors regulating the

differenti-ation and the proliferdifferenti-ation of monocytes

/

macrophages,

it is possible to assume that peritoneal cells from double

knockout mice could represent immature macrophages

or poorly differentiated monocytic cells. In fact,

M-CSF knockout mice are known to develop osteopetrosis

which is caused by immaturation of osteoclast, a

resi-dent macrophage [54,55]. Moreover, it is reported that

Ox-LDL is able to induce the differentiation of

mono-cytes into macrophages [56]. These findings suggested

that the effect of Ox-LDL on immature macrophages

might

differ

in

quality

from

that

on

mature

macrophages.

Acknowledgements

This work was supported in part by a grant form

Ono Medical Research Foundation.

References