Cell cycle protein expression in vascular smooth muscle cells in vitro and in vivo is regulated through phosphatidylinositol 3-kinase and mammalian target of rapamycin.

Cell cycle progression represents a key event in vascular proliferative diseases, one that depends on an increased rate of protein synthesis. An increase in phosphatidylinositol 3-kinase (PI 3-kinase) activity is associated with vascular smooth muscle cell proliferation, and rapamycin, which blocks the activity of the mammalian target of rapamycin, inhibits this proliferation in vitro and in vivo. We hypothesized that these 2 molecules converge on a critical pathway of translational regulation that is essential for successful upregulation of cell cycle-regulatory proteins in activated smooth muscle cells. p70(S6) kinase, a target of PI 3-kinase and the mammalian target of rapamycin, was rapidly activated on growth factor stimulation of quiescent coronary artery smooth muscle cells and after balloon injury of rat carotid arteries. The translational repressor protein 4E-binding protein 1 was similarly hyperphosphorylated under these conditions. These events were associated with increases in the protein levels of cyclin B1, cyclin D1, cyclin E, cyclin-dependent kinase 1, cyclin-dependent kinase 2, proliferating cell nuclear antigen, and p21(Cip1) in vivo and in vitro, whereas inhibition of the PI 3-kinase signaling pathway with either rapamycin or wortmannin blocked the upregulation of these cell cycle proteins, but not mRNA, and arrested the cells in vitro before S phase. In contrast to findings in other cell types, growth factor- or balloon injury-induced downregulation of the cell cycle inhibitor p27(Kip1) was not affected by rapamycin treatment. These data suggest that cell cycle progression in vascular cells in vitro and in vivo depends on the integrity of the PI 3-kinase signaling pathway in allowing posttranscriptional accumulation of cell cycle proteins.

[NO-synthase and cardiovascular gene therapy]. / NO-Synthase und kardiovaskuläre Gentherapie.

Molecular biology research of vascular remodeling paved the way to novel therapeutic approaches in experimental cardiology. Using gene transfer methods in various animal models, it has been shown that overexpression of nitric oxide synthase (NOS) can inhibit neointimal lesion proliferation. This review summarizes pivotal data regarding NO synthase gene manipulation in the cardiovascular system which enabled transition of this experimental approach from the bench to the clinical arena.

A pressure-mediated nonviral method for efficient arterial gene and oligonucleotide transfer.

In this study, we report a method of controlled pressure-mediated delivery of "naked" DNA that achieves efficient and safe arterial gene and oligonucleotide transfer. We demonstrated a pressure-dependent uptake of fluorescein-labeled (FITC) oligonucleotide (ODN) in rabbit carotid arteries with preexisting neointimal hyperplasia, using nondistending intravascular delivery pressures ranging from 0 to 760 mm Hg. At an infusion pressure of 50 mm Hg, 10.5+/-5% of neointimal cell nuclei were positive for nuclear uptake of FITC-ODN 4 days after transfection. With an infusion pressure of 760 mm Hg, the transfection efficiency increased to 84.2+/-5.3% of neointimal cells, and to 64.5+/-11.6 and 92.4+/-5.5% of medial and adventitial cells, respectively. Similar patterns of FITC-ODN uptake were seen in atherosclerotic injured arteries. We also investigated the pressure-mediated delivery of plasmid DNA. Transfection of a luciferase expression plasmid, using an infusion pressure of 760 mm Hg, yielded luciferase expression of 816.6+/-108.6 fg/mg protein in normal rabbit carotid arteries, as compared with 38.9+/-23.7 fg/mg protein at 100 mm Hg. Luciferase expression was significantly higher in pressure-transfected injured atherosclerotic arteries (5467.3+/-1047.6 fg/mg protein at 760 mm Hg). Transfection of beta-galactosidase indicated that significant transgene expression occurred in the neointima and media. These data indicate that this pressure-mediated transfection method yields efficient oligonucleotide delivery and enhances transduction with plasmid DNA in normal as well as injured nonatherosclerotic or atherosclerotic arteries.

A novel role for the cyclin-dependent kinase inhibitor p27(Kip1) in angiotensin II-stimulated vascular smooth muscle cell hypertrophy.

Angiotensin II (Ang II) has been shown to stimulate either hypertrophy or hyperplasia. We postulated that the differential response of vascular smooth muscle cells (VSMCs) to Ang II is mediated by the cyclin-dependent kinase (Cdk) inhibitor p27(Kip1), which is abundant in quiescent cells and drops after serum stimulation. Ang II treatment (100 nM) of quiescent VSMCs led to upregulation of the cell-cycle regulatory proteins cyclin D1, Cdk2, proliferating cell nuclear antigen, and Cdk1. p27(Kip1) levels, however, remained high, and the activation of the G1-phase Cdk2 was inhibited as the cells underwent hypertrophy. Overexpression of p27(Kip1) cDNA inhibited serum-stimulated [(3)H]thymidine incorporation compared with control-transfected cells. This cell-cycle inhibition was associated with cellular hypertrophy, as reflected by an increase in the [(3)H]leucine/[(3)H]thymidine incorporation ratio and by an increase in forward-angle light scatter during flow cytometry at 48 hours after transfection. The role of p27(Kip1) in modulating the hypertrophic response of VSMCs to Ang II was further tested by antisense oligodeoxynucleotide (ODN) inhibition of p27(Kip1) expression. Ang II stimulated an increase in [(3)H]thymidine incorporation and the percentage of S-phase cells in antisense ODN-transfected cells but not in control ODN-transfected cells. We conclude that p27(Kip1) plays a role in mediating VSMC hypertrophy. Ang II stimulation of quiescent cells in which p27(Kip1) levels are high results in hypertrophy but promotes hyperplasia when levels of p27(Kip1) are low, as in the presence of other growth factors.

DNA transfer into vascular smooth muscle using fusigenic Sendai virus (HVJ)-liposomes.

Manipulation of the genetic machinery of cells both in vitro and in vivo is becoming an ever more important means of elucidating pathways of molecular and cellular biochemistry. In addition, gene therapy has been proposed as a novel and potentially powerful treatment for both inherited and acquired diseases. Successful gene transfer and gene blockade generally depend on high efficiency delivery of exogenous DNA or RNA into living cells, and much effort has therefore been focused on the development of methods for achieving this delivery in a safe and effective manner. We describe here our application of fusigenic Sendai virus (HVJ)-liposome technology toward the effective delivery of DNA into vascular smooth muscle cells (VSMC) in cell culture. Cellular uptake and intracellular distribution of oligodeoxynucleotide (ODN) after transfection with HVJ-liposome complexes was characterized using fluorescent (FITC)-labeled ODN, and the biologic effect of HVJ-liposome mediated transfection was demonstrated via inhibition of DNA synthesis in cultured VSMC using antisense ODN against basic fibroblast growth factor.

Cell cycle inhibition preserves endothelial function in genetically engineered rabbit vein grafts.

We have recently shown that ex vivo gene therapy of rabbit autologous vein grafts with antisense oligodeoxynucleotides (AS ODN) blocking cell cycle regulatory gene expression inhibits not only neointimal hyperplasia, but also diet-induced, accelerated graft atherosclerosis. We observed that these grafts remained free of macrophage invasion and foam cell deposition. Since endothelial dysfunction plays an important role in vascular disease, the current study examined the effect of this genetic engineering strategy on graft endothelial function and its potential relationship to the engineered vessels' resistance to atherosclerosis. Rabbit vein grafts transfected with AS ODN against proliferating cell nuclear antigen (PCNA) and cell division cycle 2 (cdc2) kinase elaborated significantly more nitric oxide and exhibited greater vasorelaxation to both calcium ionophore and acetylcholine than did untreated or control ODN-treated grafts. This preservation of endothelial function was associated with a reduction in superoxide radical generation, vascular cell adhesion molecule-1 (VCAM-1) expression, and monocyte binding activity in grafts in both normal and hypercholesterolemic rabbits. Our data demonstrate that AS ODN arrest of vascular cell cycle progression results in the preservation of normal endothelial phenotype and function, thereby influencing the biology of the vessel wall towards a reduction of its susceptibility to occlusive disease.

Gene inhibition and gene augmentation for the treatment of vascular proliferative disorders.

Gene therapy is emerging as a potential strategy for the treatment of vasculoproliferative diseases such as restenosis after angioplasty, vascular bypass graft occlusion and transplant coronary vasculopathy for which no known effective therapy exists. Our laboratory has demonstrated that vascular smooth muscle proliferation and lesion formation can be prevented by the blockade of genes regulating cell cycle progression. With this approach it was also shown that genetically engineered bioprostheses can be developed that are resistant to accelerated atherosclerosis and thus to graft failure. We have also reported that the direct in vivo transfer of a cDNA encoding endothelial nitric oxide synthase resulted in inhibition of neointimal lesion formation and improvement of vascular reactivity, demonstrating that therapeutic effects can also be achieved by the in vivo transfer of gene(s) whose product(s) exert a paracrine effect on the vessel wall.

Expression of inducible nitric oxide synthase in human heart failure.

BACKGROUND: There is increasing evidence that alterations in nitric oxide synthesis are of pathophysiological importance in heart failure. A number of studies have shown altered nitric oxide production by the endothelial constitutive isoform of nitric oxide synthase (NOS), but there is very little information on the role of the inducible isoform. METHODS AND RESULTS: We analyzed inducible NOS (iNOS) expression in ventricular myocardium taken from 11 control subjects (who had died suddenly from noncardiac causes), from 10 donor hearts before implantation, and from 51 patients with heart failure (24 with dilated cardiomyopathy [DCM], 17 with ischemic heart disease [IHD], and 10 with valvular heart disease [VHD]). Reverse transcription-polymerase chain reaction was used to confirm the presence of intact mRNA and to detect expression of iNOS and atrial natriuretic peptide (ANP). ANP was used as a molecular phenotypic marker of ventricular failure. iNOS was expressed in 36 of 51 biopsies (71%) from patients with heart failure and in none of the control patients (P<.0001). iNOS expression could also be detected in 50% of the donor hearts. All samples that expressed iNOS also expressed ANP. iNOS gene expression occurred in 67% of patients with DCM, 59% of patients with IHD, and 100% of patients with VHD. To determine whether iNOS protein was expressed in failing ventricles, immunohistochemistry was performed on three donor hearts and nine failing hearts with iNOS mRNA expression. Staining for iNOS was almost undetectable in the donor myocardium and in control sections, but all failing hearts showed diffuse cytoplasmic staining in cardiac myocytes. Expression of iNOS could be observed in all four chambers. Western blot analysis with the same primary antibody showed a specific positive band for iNOS protein in the heart failure specimens; minimal iNOS protein expression was seen in donor heart samples. CONCLUSIONS: iNOS expression occurs in failing human cardiac myocytes and may be involved in the pathophysiology of DCM, IHD, and VHD.

[Experimental approaches for gene therapy modification of vascular remodeling]. / Experimentelle Ansätze zur gentherapeutischen Beeinflussung des vaskulären Remodellings.

The active process of vascular remodeling involves changes in several cellular processes like cell growth, cell death, cell migration, and extracellular matrix production or degradation. The recent development of in vivo gene transfer technology has created a powerful new tool for the study of vascular remodeling by providing methods to overexpress or to inhibit specific local factors which are believed to contribute to the process of structural changes within the vasculature. The following overview describes recently published studies which investigated the effects of gene overexpression or inhibition on the process of vascular remodeling. The technology of gene transfer provides the opportunity for the development of novel therapeutic strategies such as gene replacement, gene correction, or gene augmentation, thus paving the way for gene therapy as treatment for vascular disease.

Gene therapy inhibiting neointimal vascular lesion: in vivo transfer of endothelial cell nitric oxide synthase gene.

It is postulated that vascular disease involves a disturbance in the homeostatic balance of factors regulating vascular tone and structure. Recent developments in gene transfer techniques have emerged as an exciting therapeutic option to treat vascular disease. Several studies have established the feasibility of direct in vivo gene transfer into the vasculature by using reporter genes such as beta-galactosidase or luciferase. To date no study has documented therapeutic effects with in vivo gene transfer of a cDNA encoding a functional enzyme. This study tests the hypothesis that endothelium-derived nitric oxide is an endogenous inhibitor of vascular lesion formation. After denudation by balloon injury of the endothelium of rat carotid arteries, we restored endothelial cell nitric oxide synthase (ec-NOS) expression in the vessel wall by using the highly efficient Sendai virus/liposome in vivo gene transfer technique. ec-NOS gene transfection not only restored NO production to levels seen in normal untreated vessels but also increased vascular reactivity of the injured vessels. Neointima formation at day 14 after balloon injury was inhibited by 70%. These findings provide direct evidence that NO is an endogenous inhibitor of vascular lesion formation in vivo (by inhibiting smooth muscle cell proliferation and migration) and suggest the possibility of ec-NOS transfection as a potential therapeutic approach to treat neointimal hyperplasia.