ICAM-1 deficiency reduces atherosclerotic lesions in double-knockout mice (ApoE(-/-)/ICAM-1(-/-)) fed a fat or a chow diet.

Intercellular adhesion molecule (ICAM)-1, a major adhesion molecule, plays a critical role in the homing of leukocytes to sites of atherosclerotic lesions. However, very little is known on the role of ICAM-1 in initiating and perpetuating vascular lesions in ApoE(-/-) mice fed a chow or a fat diet. This study has investigated the mean aortic lesions in mice (C57BL6 background) with a single-knockout (ApoE(-/-)) or double-knockout (DKO; ApoE(-/-), ICAM-1(-/-)) fed a chow or a fat diet over a period of 3, 6, 15, and 20 weeks. A 3-fold reduction in lesion size was observed at all time points in DKO mice fed a chow diet. However, in DKO mice fed a fat diet, a marked reduction in the aortic lesion was observed at 3 and 15 weeks, which did not reach a significant level at 6 and 20 weeks. This study shows in essence that DKO mice are protected from developing significant lesions for up to 6 weeks when fed a chow diet and from 3 to 6 weeks when fed a fat diet. After 6 weeks, the lesion size of the DKO mice follows that of the single-knockout mice when fed a chow diet and gets to the same level in mice fed a fat diet. Plasma cholesterol levels were not altered as a result of ICAM-1 deficiency. These studies show that ICAM-1 is implicated in the formation and progression of atherosclerotic lesions.

Modulation of expression of endothelial intercellular adhesion molecule-1, platelet-endothelial cell adhesion molecule-1, and vascular cell adhesion molecule-1 in aortic arch lesions of apolipoprotein E-deficient compared with wild-type mice.

Human vascular adhesion molecules, such as intercellular adhesion molecule-1 (ICAM-1), platelet-endothelial cell adhesion molecule-1 (PECAM-1), and vascular cell adhesion molecule-1 (VCAM-1), are thought to play a critical role in the homing of leukocytes to sites of atherosclerotic lesions. However, very little is known about the expression of adhesion molecules in the vasculature of mice models, such as apolipoprotein E knockout (apoE(-/-)) mice, the lesions of which closely mimic human atherosclerotic lesions. This study has first quantitatively characterized the mean expression of endothelial adhesion molecules, lining the whole vessel intimal circumference, over a period of time (0 to 20 weeks of diet) in aortic arch lesions of male apoE-deficient compared with wild-type (C57BL/6) mice. These animals were fed a chow or a cholesterol-rich diet. ApoE(-/-) animals showed first an increase (at 6 weeks) and then a reduction (at 16 weeks) in the mean expression of ICAM-1 (P<0.05) and PECAM-1 (P<0.05) but not VCAM-1 levels. Such modulation of the mean expression of adhesion molecules was not observed in wild-type mice. Confirmation of immunohistochemistry results on ICAM-1 was obtained by Northern blots performed on the aortic arch of apoE and C57BL6 chow-fed mice over a period of 20 weeks. Moreover, the presence of VCAM-1 was also confirmed at the RNA level, on aortas of control and apoE mice, by reverse transcription-polymerase chain reaction. In the second part of the study, we assayed the levels of adhesion molecules, in different types of histologically defined atherosclerotic lesions, in apoE(-/-) animals fed for 20 weeks. All 3 adhesion molecules (ICAM-1, PECAM-1, and VCAM-1) were observed to be reduced in fibrofatty and complex lesions but not in fatty streaks or in areas without lesions. These results indicate that the expression of these adhesion molecules in apoE-deficient animals varies with the evolution of the plaque from a fatty to a fibrous stage.

Identification and cloning of a new gene (2A3-2), homologous to human translational elongation factor, upregulated in a proliferating rat smooth muscle cell line and in carotid hyperplasia.

Smooth muscle cells (SMCs), before migration and proliferation in the intima of the vessel wall, change from a normal contractile to a pathological proliferating phenotype. The molecular regulatory mechanisms implicated in such phenotypic changes remain poorly understood. In this study, using differential display, we have isolated for the first time a new gene (2A3-2) that is overexpressed in a rapidly proliferating, but not synthetic, rat SMC line. This was further confirmed by northern blot performed on the 2 cell types. Moreover, balloon catheter injury of rat carotids showed, by a virtual northern technique, an upregulation of this new gene in hyperplasia vessels. This new gene (2A3-2, 1.2 kb) was present in skeletal muscle, heart, aorta, lung, liver, kidney, and spleen. In addition, 5' rapid amplification of cDNA ends (5' RACE) allowed the cloning and sequencing of this 1.2-kb gene. Comparison of this newly identified gene sequence with data banks showed a strong homology to human and bovine mitochondrial translational elongation factor. The 2A3-2 gene, identified in this study, may play a vital role in the cascade of events implicated in switching SMC phenotype from a quiescent to a proliferate one.

Transformed rat arterial smooth muscle cells induce platelet aggregation.

Atherogenesis is characterized by a proliferation of arterial smooth muscle cells that may be of transformed nature. Platelets are implicated in the progression of atherosclerotic lesions through thrombotic complications. The present study was designed to investigate whether transformed arterial smooth muscle cells (SMC) could specifically aggregate platelets. We used rat transformed arterial SMC lines, V6- and V8-lines, that we had previously established. Experiments were performed with an in vitro homologous rat system. Suspensions of SMC were added without any other aggregating agent to rat heparinized platelet-rich plasma (PRP) in a coagulo-aggregometer. The effect of transformed V6-line and V8-line SMC was compared to that of their normal parental counterparts, V6- and V8-parent cells. Suspensions of transformed SMC induced, in a dose-dependent manner, an immediate and reversible ADP-like platelet aggregation. The amplitude of platelet aggregation was much higher with addition of transformed cells than of the corresponding control SMC (7.39 +/- 0.75 cm vs. 0.85 +/- 0.62 cm with 2 x 10(6) SMC, V6-line vs. V6-parent cells, respectively). ADP-like aggregation did not significantly differ between the two transformed V6- and V8-lines. ADP-like platelet aggregation was also obtained with supernatants of transformed SMC suspensions, the amplitude being higher with supernatants than with cell suspensions (21.0 +/- 3.64 cm vs. 6.8 +/- 1.22 cm with 1.0 x 10(6) V8-line cells, supernatant vs. cell suspension, respectively). The transformed SMC-induced aggregation of platelets was inhibited by apyrase (125 microM) and iodoacetate (25 mM) and thus was ascribable to ADP released by the SMC. In addition, all suspensions of SMC, normal or transformed, but not their supernatants, induced plasma clotting after variable coagulation times. Coagulation was inhibited by hirudin (25 to 100 U/ml) and phospholipase A2 (10 U/ml) indicating thrombin generation through activity of the SMC membrane tissue factor. The present results show that transformed arterial smooth muscle cells may directly aggregate platelets via a release of ADP and this could be of pathophysiological relevance for thrombosis associated with atherosclerosis.

Lipid biosynthesis in cultured arterial smooth muscle cells is related to their phenotype.

During the atherogenic process in vivo, arterial smooth muscle cells (SMC) undergo changes in their phenotype. In the present study, rat SMC from primary cultures and from subcultures before 10 and after 200 passages, showing contractile-like, synthetic and transformed phenotypes, respectively, were compared in regard to their lipid content and biosynthesis. The rationale for comparing these phenotypes rests in the similar changes in phenotype of SMC that occur in the formation and progression of atherosclerotic lesions. Phenotype changes were shown to be associated with changes in the phospholipid content of SMC. Phospholipid levels increased, but not as significantly as did cholesterol levels when passing from contractile to synthetic and transformed cells (1.23 +/- 0.18, 2.28 +/- 0.26 and 3.25 +/- 0.23 micrograms/10(6) cells, respectively). Cholesterol normalized in respect to cell protein was increased to the same extent. Lipid synthesis as judged by [14C]acetate incorporation was increased 3- to 12-fold in the synthetic and transformed cells, respectively, compared to contractile cells. After thin-layer chromatography, radioactivity was shown to be markedly increased in most of the lipid fractions, but label in the cholesterol fraction of synthetic and transformed cells was increased by 7- and 21-fold, respectively. Thus, SMC in vitro were shown to drastically increase cholesterol biosynthesis associated with phenotype changes. Such changes are known to occur in vivo and might represent a critical step in the deposition of excess cholesterol within foam cells.

Isolation of two morphologically distinct cell lines from rat arterial smooth muscle expressing high tumorigenic potentials.

Smooth muscle cell proliferation is an important feature of atherogenesis. Some works have hypothesized that a transformation of smooth muscle cells could arise during this pathological process. The present paper describes two spontaneously transformed cell lines of arterial smooth muscle cells (SMC) established from aortic media of adult rat. The cell lines have been designated V6 and V8; some of their morphologic, growth, and metabolic characteristics are described and compared to their parent cells. The two cell lines appeared distinct by their morphology and by their degree of transformation. V6 cells appeared as elongated spindle-shaped cells whereas V8 cells were spread cells with a cobblestone pattern. Karyotypes of both cell lines showed a high polyploidy level. V6 and V8 cell lines were immortalized and showed growth characteristics of transformed cells: low requirement of serum to grow, ability to form colonies in soft agar and tumorigenicity in nude mice; V8 cells presented a higher malignancy than V6 cells. Both V6 and V8 cells exhibited characteristics of cultured arterial SMC: ultrastructure, alpha actin expression at the protein and mRNA level, prostacyclin production. The remarkably different morphologies of the V6 and V8 lines and their transformed phenotype suggest that these cell lines could be useful models to study SMC differentiation and proliferation with respect to atherosclerotic or hypertensive vascular diseases.

[Modulation of arterial smooth muscle cells in culture and cholesterol exchange]. / Modulation des cellules musculaires lisses artérielles en culture et mouvements de cholestérol.

The phenotypic modulation and the enhanced proliferation of smooth muscle cells (SMC) as well as their foam transformation are major processes in arterial pathophysiology and during atherogenesis. Arterial SMC play a crucial role, in response to several stimuli: the SMC "activation" is an essential condition leading to the adult atherosclerotic plaque formation. Owing to the difficulty to study the SMC regulation in vivo, most of the literature in this field refers to in vitro models. Modulated SMC in culture, changing from a contractile to a synthetic state, share similar features with atherosclerotic plaques cells. The phenotypic modulation of SMC is expressed by morphological, biochemical, metabolic and functional modifications. The regulation of cholesterol movements might influence the foam transformation process of arterial SMC.