To isolate the genes involved in the cell cycle G1 phase progression of arterial smooth muscle cells (SMCs), a cDNA clone (M11) was previously selected by differential hybridization screening of a mid-G1 serum-stimulated SMC cDNA library. The delay of induction after mitogenic stimulation, time of expression, and need for new protein synthesis for full expression made it possible to classify this gene in the "delayed early" gene group. Determination of the partial M11 cDNA sequence showed full homology with the osteopontin gene (secreted phosphoprotein 1, 2ar), an Arg-Gly-Asp-containing extracellular matrix protein. Osteopontin mRNA was also detected in the aorta at levels as high as in the kidney but lower than in bone, two tissues in which it has been previously detected. In vitro analysis of osteopontin expression in serum-stimulated quiescent SMCs and asynchronously cycling SMCs demonstrated that osteopontin overexpression was associated with SMC proliferation. In view of our results, the high osteopontin expression observed by others in the injured carotid artery could be explained by the involvement of SMCs in the proliferative process. Taken together, these results suggest that osteopontin may play an important role in pathological processes that are associated with arterial SMC proliferation, such as atherosclerosis or restenosis.
Cleavage and subsequent release of the extracellular domains of receptor protein tyrosine phosphatases (RPTP) occur at high cell density and may have an important role in regulating their activity. Because cleavage of RPTP occurs at a target motif (RXK/RR) recognized by a family of subtilisin/kexin-like endoproteases, we postulated that members of the subtilisin family may have an important role in this cleavage. We show in this report that the membrane-associated RPTPmu--both in its full 200-kDa form and as a 100-kDa cleavage product--is upregulated 4- and 7-fold, respectively, as human umbilical vein endothelial cells (HUVEC) approach confluence. To determine whether RPTPmu cleavage depended on PC5 (a subtilisin/kexin like endoprotease present in endothelial cells), we transfected COS cells with expression plasmids coding for RPTPmu and PC5 or the closely related protease PACE4. PC5, but not PACE4, cleaved RPTPmu, and RPTPmu cleavage was absent in COS cells transfected with an expression plasmid encoding a mutant PC5 whose active-site serine had been mutated to alanine. We also performed RNA blot analysis to determine whether PC5 expression was affected by confluence in HUVEC. PC5 mRNA levels were upregulated by more than 30-fold when confluence in HUVEC increased from 25% to 100%. These results indicate that PC5 may have an important role in mediating the cleavage of RPTPmu in response to contact inhibition in HUVEC.
Because exogenous ATP is suspected to influence the proliferative process, its effects on the cell cycle progression of arterial smooth muscle cells were studied by investigating changes in the mRNA steady-state level of cell cycle-dependent genes. Stimulation of cultured quiescent smooth muscle cells by exogenous ATP induced chronological activation not only of immediate-early but also of delayed-early cell cycle-dependent genes, which were usually expressed after a mitogenic stimulation. In contrast, ATP did not increase late G1 gene mRNA level, demonstrating that this nucleotide induces a limited cell cycle progression of arterial smooth muscle cells through the G1 phase but is not able by itself to induce crossing over the G1-S boundary and consequently DNA synthesis. An increase in c-fos mRNA level was also induced by ADP but not by AMP or adenosine. Moreover, 2-methylthioadenosine 5'-triphosphate but not alpha, beta-methyleneadenosine 5'-triphosphate mediated this kind of response. Taken together, these results demonstrate that extracellular ATP induces the limited progression of arterial smooth muscle cells through the G1 phase via its fixation on P2 gamma receptors.
mRNA of the P2u purinoceptor (or nucleotide receptor) is detected both by polymerase chain reaction or Northern blot analyses in cultured aortic smooth muscle cells. When added to the culture medium of these cells, UTP, a specific ligand of the P2u receptor, induces an increased expression of both immediate-early and delayed-early cell cycle-dependent genes. This induction demonstrates similar features (kinetics, concentration dependence) to those obtained after stimulation of aortic smooth cells by exogenous ATP, a common ligand for most P2 purinoceptors. In contrast, 2-methylthioATP, a preferential ligand for P2y purinoceptors, induces only a significant increase of immediate-early genes but not of delayed-early genes. Moreover, the 2-methylthioATP-induced responses (c-fos mRNA increase, free intracellular calcium transient) are lower than those induced by ATP or UTP and are complementary to those of UTP. These results demonstrate that functional P2u receptors are present on cultured aortic smooth muscle cells and suggest that the bulk of responses induced by extracellular ATP on cell cycle progression are mediated via P2u purinoceptors, a hypothesis confirmed by cytofluorometric studies. Since some ATP- or UTP-induced genes code for chemotactic proteins (monocyte chemoattractant protein-1 and osteopontin), this study suggests that these nucleotides may contribute to vascular or blood cell migration and proliferation and consequently to the genesis of arterial diseases.
Serum stimulation of arterial smooth muscle cells in culture induces a progression through the cell cycle and cell proliferation. Most genes previously described as cell cycle-dependent in various cell types also demonstrate a cell cycle-dependent expression in arterial smooth muscle cells. As in other cell types, these genes can be classified into three groups according to their mode of expression: "immediate early" genes (c-fos, c-myc, ...), "delayed early" genes (2F1, ...), and "late-G1" genes (proliferating cell nuclear antigen, thymidine kinase, . . .). In addition to these previously described genes, three genes isolated from a cDNA library of stimulated smooth muscle cells have been demonstrated to be cell cycle-dependent: A21, the rat JE gene, and L51 can be classified as "immediate early" genes, while M11 represents a new member of the "delayed early" gene family.
The expression of a set of cell cycle dependent (CCD) genes (c-fos, c-myc, ornithine decarboxylase (ODC), and thymidine kinase (TK)) was comparatively studied in cultured arterial smooth muscle cells (SMC) during exit from quiescence and exponential proliferation. These genes, which were not expressed in quiescent SMC, were chronologically induced after serum stimulation. c-fos mRNA were rapidly and transiently expressed very early in the G1 phase; c-myc and ODC peaked a few hours after serum stimulation and then remained at an intermediary level throughout the first cell cycle; TK mRNA and activity then appeared at the G1/S boundary and peak in G2/M phases. Except for c-fos, the other genes were also expressed in asynchronously cycling SMC (ACSMC); their expression was studied in elutriated subpopulations representative of cell cycle progression. c-fos mRNA were undetectable in any sorted subpopulations, even in the pure early G1 population. Despite a slight increase as the cell cycle advanced, c-myc and ODC genes were expressed throughout the ACSMC cell cycle. A faint TK activity was found in G1 subpopulations and increased in populations enriched in other phases; in contrast, TK mRNA remained highly expressed in all elutriated subpopulations. This study demonstrates significant modulations in CCD gene expression between quiescent stimulated and asynchronously cycling SMC in culture. This suggests that the events occurring during the emergence of SMC from quiescence are probably different from those in the G1 phase of ACSMC.
mRNA of the P2u purinoceptor (or nucleotide receptor) is detected both by polymerase chain reaction or Northern blot analyses in cultured aortic smooth muscle cells. When added to the culture medium of these cells, UTP, a specific ligand of the P2u receptor, induces an increased expression of both immediate-early and delayed-early cell cycle-dependent genes. This induction demonstrates similar features (kinetics, concentration dependence) to those obtained after stimulation of aortic smooth cells by exogenous ATP, a common ligand for most P2 purinoceptors. In contrast, 2-methylthioATP, a preferential ligand for P2y purinoceptors, induces only a significant increase of immediate-early genes but not of delayed-early genes. Moreover, the 2-methylthioATP-induced responses (c-fos mRNA increase, free intracellular calcium transient) are lower than those induced by ATP or UTP and are complementary to those of UTP. These results demonstrate that functional P2u receptors are present on cultured aortic smooth muscle cells and suggest that the bulk of responses induced by extracellular ATP on cell cycle progression are mediated via P2u purinoceptors, a hypothesis confirmed by cytofluorometric studies. Since some ATP- or UTP-induced genes code for chemotactic proteins (monocyte chemoattractant protein-1 and osteopontin), this study suggests that these nucleotides may contribute to vascular or blood cell migration and proliferation and consequently to the genesis of arterial diseases.
An increase in cell size and protein content was observed when quiescent arterial smooth muscle cells in culture were incubated with either angiotensin I1 or 111. These effects were inhibited by the specific angiotensin type-1 receptor antagonist losartan (DuP 753) but not by CGP 421 12A. In parallel, a transient and dose-dependent induction of czfos was demonstrated not only with angiotensins I1 and I11 but also with angiotensin I. Both angiotensins I1 and 111 exerted their maximal effect at 1 pM, while angiotensin I needed a tenfold-higher concentration to exert an identical effect. As for hypertrophy, losartan also inhibits angiotensin-induced c-fos expression, suggesting that this gene may be involved into the hypertrophic process. Angiotensin-I-mediated c-jos induction is partially inhibited by the angiotensin-converting enzyme inhibitors captopril and trandolaprilate; given that an angiotensin-converting enzyme activity was detected in these smooth muscle cell cultures, these results suggest that angiotensin-I-induced c-fos expression is mediated in part via angiotensin-I conversion to angiotensin 11, but also by other unidentified pathway(s). Angiotensin I could essentially induce smooth muscle cell hypertrophy by indirect mechanisms, while angiotensins I1 and 111 act directly on smooth muscle cells.The effect of hypertension on the arterial wall is characterized by an increase in smooth muscle mass due to cellular hypertrophy and/or hyperplasia (for review, see [l]). In chronic hypertension models such as spontaneously hypertensive rats (SHR) or two-kidney one-clip Goldblatt hypertensive rats, the increased mass of smooth muscle cells (SMC) in aortas is due principally to SMC hypertrophy [2-41. In contrast, an increase in medial SMC number, resulting from their proliferation, is accounted for by the increase in smooth muscle mass in models of acute severe hypertension such as aortic coarctation [5, 61. Factors inducing in vivo arterial SMC hypertrophy are not yet well defined. However, some reports suggest that the vasoconstrictor peptide angiotensin (Ang) I1 may play a role in this induction. Indeed, administration of angiotensin-converting enzyme (ACE) inhibitors decreases SMC hypertrophy in the aorta of SHR during the development of hypertension. As this effect is not entirely mediated by reduction in blood pressure, it has been postulated that local angiotensin may participate in the development of SMC hypertrophy [7, 81. In vitro data corroborate the role of AngII in SMC hypertrophy, since AngII induces an increase in cell volume and protein content in quiescent aortic SMC in culture [9 -111. In addition
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.