Requirement for generation of H2O2 for platelet-derived growth factor signal transduction

Stimulation of rat vascular smooth muscle cells (VSMCs) by platelet-derived growth factor (PDGF) transiently increased the intracellular concentration of hydrogen peroxide (H2O2). This increase could be blunted by increasing the intracellular concentration of the scavenging enzyme catalase or by the chemical antioxidant N-acetylcysteine. The response of VSMCs to PDGF, which includes tyrosine phosphorylation, mitogen-activated protein kinase stimulation, DNA synthesis, and chemotaxis, was inhibited when the growth factor-stimulated rise in H2O2 concentration was blocked. These results suggest that H2O2 may act as a signal-transducing molecule, and they suggest a potential mechanism for the cardioprotective effects of antioxidants.

Gene therapy for vascular disease

Highly efficient methods that are now available allow for the genetic modification of cells that compose the vessel wall. The application of these gene transfer systems are already providing information that has enhanced our understanding of a variety of cellular processes relating to vascular biology. Recent experimental results using this technology also hold promise for more powerful therapeutic options in the treatment of vascular disease. This review discusses the most commonly used methods of gene transfer and details some current applications of these methodologies in animal models of vascular disease.

In vivo suppression of injury-induced vascular smooth muscle cell accumulation using adenovirus-mediated transfer of the herpes simplex virus thymidine kinase gene

Restenosis, a process characterized in part by excessive smooth muscle cell (SMC) proliferation in areas of vascular injury, occurs in up to 50% of patients undergoing balloon angioplasty. In an effort to develop a treatment strategy for restenosis, we constructed a replication-deficient recombinant adenovirus (AdMLP.HSTK) containing the herpes simplex virus thymidine kinase gene (HSV tk). This viral gene product phosphorylates the prodrug ganciclovir to form a nucleoside analog that inhibits DNA synthesis. Cultured primary rat SMCs infected with AdMLP.HSTK were completely growth-inhibited by incubation in ganciclovir-containing medium. In addition, when only a portion of the SMC population received the HSV tk transgene, an inhibitory effect on neighboring SMCs was evident. Evaluation of this strategy in vivo using a rat carotid balloon injury model demonstrated that local infection of injured arteries with AdMLP.-HSTK followed by 2 weeks of systemic ganciclovir treatment significantly (P < 0.01) reduced injury-induced SMC accumulation. In contrast, there was no suppression of injury-induced SMC accumulation in animals infected with AdMLP.HSTK but not receiving ganciclovir or in those animals infected with a control adenovirus and either treated or not treated with ganciclovir. These results demonstrate the potential utility of adenovirus-mediated gene transfer for treatment of restenosis after balloon injury.

Ras proteins regulate multiple mitogenic pathways in A10 vascular smooth muscle cells

We examined the role of ras proteins in mitogenesis and proliferation of A10 smooth muscle cells. An assay was developed in which a dominant negative ras gene could be transiently expressed in vascular smooth muscle cells. As opposed to cells transfected with a control plasmid, those transfected with a dominant negative ras expression plasmid exhibited a decrease in thymidine uptake in response to serum, platelet-derived growth factor, epidermal growth factor, fibroblast growth factor and thrombin stimulation. In addition, expression of dominant negative ras blocked smooth muscle cell proliferation as assessed by the number of surviving colonies after transfection and neomycin selection. Our data is the first to show that ras is essential for smooth muscle cell proliferation and is a mediator in multiple smooth muscle cell mitogenic signalling pathways.

Potential role of human cytomegalovirus and p53 interaction in coronary restenosis

A subset of patients who have undergone coronary angioplasty develop restenosis, a vessel renarrowing characterized by excessive proliferation of smooth muscle cells (SMCs). Of 60 human restenosis lesions examined, 23 (38 percent) were found to have accumulated high amounts of the tumor suppressor protein p53, and this correlated with the presence of human cytomegalovirus (HCMV) in the lesions. SMCs grown from the lesions expressed HCMV protein IE84 and high amounts of p53. HCMV infection of cultured SMCs enhanced p53 accumulation, which correlated temporally with IE84 expression. IE84 also bound to p53 and abolished its ability to transcriptionally activate a reporter gene. Thus, HCMV, and IE84-mediated inhibition of p53 function, may contribute to the development of restenosis.

The basis of molecular strategies for treating coronary restenosis after angioplasty

Excessive smooth muscle cell proliferation significantly contributes to restenosis, which occurs in 25% to 50% of patients within 6 months of coronary angioplasty. Because successful treatment will probably depend on our acquiring a comprehensive knowledge of the molecular and cellular mechanisms involved, this report reviews 1) information relevant to the molecular and cellular mechanisms responsible for the smooth muscle cell(s) response to vascular injury, and 2) several molecular-based therapeutic strategies currently being explored as possible approaches to the control of restenosis, including recombinant DNA technology to target delivery of cytotoxic molecules to proliferating smooth muscle cell(s), antisense strategies to inhibit expression of gene products necessary for cell proliferation and gene therapy.

Dynamic actin structures stabilized by profilin

We describe the production and analysis of clonal cell lines in which we have overexpressed human profilin, a small ubiquitous actin monomer binding protein, to assess the role of profilin on actin function in vivo. The concentration of filamentous actin is increased in cells with higher profilin levels, and actin filament half-life measured in these cells is directly proportional to the steady-state profilin concentration. The distribution of actin filaments is altered by profilin overexpression. While parallel actin bundles crossing the cells are virtually absent in cells overexpressing profilin, the submembranous actin network of these cells is denser than in control cells. These results suggest that in vivo profilin regulates the stability, and thereby distribution, of specific dynamic actin structures.

Efficient gene transfer into myocardium by direct injection of adenovirus vectors

Previous studies have established that gene transfer into myocardial cells in vivo is detectable after direct injection of plasmid DNA. Recently, adenovirus vectors have been shown to provide an efficient method for gene transfer into a wide range of tissues. Therefore, this study sought to assess the efficiency and stability of adenovirus-mediated gene transfer into myocardium and to compare this method with that using plasmid-based gene transfer techniques. Adult rats underwent myocardial injection via a subdiaphragmatic approach. Gene transfer efficiency was compared using direct injection of an adenovirus vector encoding for the marker gene beta-galactosidase (beta-gal), a control adenovirus vector encoding for the cystic fibrosis transmembrane conductance regulator gene, a plasmid encoding for beta-gal, or a control plasmid. Hearts infected with an adenovirus vector containing the beta-gal gene showed significantly increased beta-gal enzymatic activity compared with hearts injected with beta-gal plasmid. Histological examination revealed that cardiac myocytes were the target of adenovirus-mediated gene transfer. A time course of gene expression showed that beta-gal enzymatic activity peaked during the first week following injection. Adenovirus vectors provide an efficient but transient method for in vivo gene expression in myocardium.

Efficient and selective adenovirus-mediated gene transfer into vascular neointima

BACKGROUND

Previous attempts to target arterial smooth muscle cells (SMCs) for gene delivery using liposomal or retroviral methods were limited by low transfection efficiency. We therefore evaluated the efficiency of adenovirus-mediated gene delivery in cultured vascular SMCs and in an in vivo model of balloon injury-induced SMC cell proliferation.

METHODS AND RESULTS

We used a recombinant adenovirus, Ad.RSV beta gal, which contained the beta-galactosidase (beta-gal) histochemical marker gene. For in vitro studies, rat aortic SMCs were incubated in media containing Ad.RSV beta gal for 5 to 120 minutes. The proportion of SMCs expressing the beta-gal gene product increased from 25% (5-minute exposure) to 80% (120-minute exposure). For in vivo studies, uninjured and injured rat carotid segments were incubated with 0.5 to 1.0 x 10(9) pfu Ad.RSV beta gal for 45 minutes. Uninjured arteries showed adenovirus-mediated gene transfer limited to the endothelium. Injured arteries were exposed to adenovirus 0, 3, 7, or 12 days after injury. In these segments, beta-gal expression was minimal with infection at 0 or 3 days after injury but marked when infection was delayed until 7 or 12 days after injury. Neointimal cells constituted the dominant target of adenovirus gene transfer, with efficiency of gene transfer ranging from 10% to > 75%. Medial SMCs, whether covered or uncovered by neointimal cells, were minimally infected. Infection with a control adenovirus vector showed no beta-gal staining.

CONCLUSIONS

Recombinant adenovirus selectively targets neointimal cells with high-efficiency gene transfer. This suggests that adenovirus vectors should be useful in targeting cells for the delivery of genes whose products may be relevant to the treatment of restenosis.

Detection and modulation in vivo of helix-loop-helix protein-protein interactions

Studies are described that allow for the in vivo detection of helix-loop-helix (HLH) protein-protein interaction. The assay used requires HLH protein-protein interaction to reconstitute a functional GAL4 transcriptional activator, which in turn activates a reporter gene placed downstream of GAL4 DNA binding sequences. Using this assay, we are able to detect intracellular heterodimerization but not homodimerization of the MyoD, E12, and Id gene products. In addition, using this system we are unable to detect stable heterodimerization between MyoD and c-Jun. We also show that expression of activated rasH gene product does not inhibit and may stabilize HLH protein-protein interaction. This system may be of general utility in studying the modulation of transcription factor interactions.

Karyoplasmic interaction selection strategy: a general strategy to detect protein-protein interactions in mammalian cells

We describe a strategy and reagents for study of protein-protein interactions in mammalian cells, termed the karyoplasmic interaction selection strategy (KISS). With this strategy, specific protein-protein interactions are identified by reconstitution of the functional activity of the yeast transcriptional activator GAL4 and the resultant transcription of a GAL4-regulated reporter gene. Reconstitution of GAL4 function results from specific interaction between two chimeric proteins: one contains the DNA-binding domain of GAL4; the other contains a transcriptional activation domain. Transcription of the reporter gene occurs if the two chimeric proteins can form a complex that reconstitutes the DNA-binding and transcriptional activation functions of GAL4. Using the KISS system, we demonstrate specific interactions for sequences from three different pairs of proteins that complex in the cytoplasm. In addition, we demonstrate that reporter genes encoding cell surface or drug-resistance markers can be specifically activated as a result of protein-protein interactions. With these selectable markers, the KISS system can be used to screen specialized cDNA libraries to identify novel protein interactions.

Alpha beta T-lymphocyte depleted mice, a model for gamma delta T-lymphocyte functional studies

Adult mice can be depleted of essentially all mature alpha beta T lymphocytes by chronic treatment with the framework-recognizing, pan-specific anti-TCR alpha beta mAb, H57-597. Similar findings have been reported in rats, gamma delta cell populations remain essentially unaltered in size and reactivity. Suppression of alpha beta T-cell development results in the loss of alloantigen reactivity and of B-cell help, suggesting that gamma delta and alpha beta populations differ in their functional capabilities. Indirect effects of the antibody treatment include quantitative changes in splenic B cells, as well as reduced sizes and weights of experimental animals. alpha beta-suppressed mice and rats may provide model systems for studies on gamma delta cell function in vivo.

Monoclonal antibody specific for an activated RAS protein

Activated RAS transforming genes that encode proteins (p21s) with amino acid substitutions at positions 12, 13, or 61 have been detected in 10-20% of human neoplasms. This report describes a monoclonal antibody (DWP) raised against a synthetic peptide corresponding to amino acids 5-16 of a mutated RAS gene encoding Val instead of Gly at position 12. DWP reacted in competition assays with peptides containing Val or Cys at position 12, but did not react with peptides containing Gly, Arg, Ser, Ala, Asp, or Glu at position 12. Immunoblot analysis of transformed NIH cells and human carcinoma cell lines showed that DWP reacts specifically with activated RAS proteins containing Val at position 12 and not with normal p21s or p21s activated by other amino acid substitutions at positions 12 and 61. Immunohistochemical studies showed that DWP-labeled transformed NIH cells and human carcinoma cells contained p21s with either Val or Cys at position 12 but not normal or other activated p21s. In contrast to the specificity seen with human carcinoma cell lines, analysis of formalin-fixed, primary carcinoma specimens indicated that positive immunoperoxidase staining with DWP did not necessarily correlate with immunoblot and transfection assays for the presence of activated RAS proteins. Immunohistochemical studies did show, however, that DWP preferentially binds human carcinoma cells.

Biological and biochemical properties of human rasH genes mutated at codon 61

Using site-directed mutagenesis, we have introduced mutations encoding 17 different amino acids at codon 61 of the human rasH gene. Fifteen of these substitutions increased rasH transforming activity. The remaining two mutants, encoding proline and glutamic acid, displayed transforming activities similar to the normal gene. Overall, these mutants vary over 1000-fold in transforming potency. Increased levels of p21 expression were required for transformation by weakly transforming mutants. The mutant proteins were unaltered in guanine nucleotide binding properties. However, all 17 different mutant proteins displayed equivalently reduced rates of GTP hydrolysis, 8- to 10-fold lower than the normal protein. There was no quantitative correlation between reduction in GTPase activity and transformation, indicating that reduced GTP hydrolysis is not sufficient to activate ras transforming potential.

Activation of ras genes in human tumors does not affect localization, modification, or nucleotide binding properties of p21

A comparison of proteins encoded by normal human ras genes and by mutant rasH or rasK genes activated in human carcinomas revealed no changes in subcellular localization, posttranslational modification, or guanine nucleotide binding associated with activation. Subcellular fractionation indicated that both normal and activated ras proteins were associated exclusively with the membrane fraction. Furthermore, both normal and activated ras proteins exhibited similar degrees of posttranslational acylation. The KD for dGTP binding was 1.0-2.2 X 10(-8) M, with no consistent differences between normal and activated ras proteins. In addition, a survey of 13 possible competing nucleotides revealed no differences in the specificity of nucleotide binding associated with ras gene activation. These results indicate that structural mutations which activate ras gene transforming activity do not alter the protein's known biochemical parameters and in particular do not affect the protein's intrinsic ability to bind guanine nucleotides.

Detection of a molecular complex between ras proteins and transferrin receptor

Immunoprecipitation of extracts of human carcinoma cell lines with three different monoclonal antibodies generated against ras proteins revealed the coprecipitation of a 90,000 dalton protein. The coprecipitated protein was identified as the transferrin receptor by comigration in both reducing and nonreducing SDS-polyacrylamide gels, by absorption with a monoclonal antibody directed against transferrin receptor, and by analysis of partial proteolysis products. Coprecipitation of the transferrin receptor with three monoclonal antibodies with differing specificities to ras proteins, as well as the inability to coprecipitate the transferrin receptor from cell extracts from which ras proteins were depleted by preabsorption, indicates that ras proteins and the transferrin receptor form a molecular complex. This complex is disrupted by addition of transferrin to cell extracts. These findings suggest that ras proteins function in regulation of cell growth via interaction with the cell surface receptor for transferrin.