Peter C. Dartsch

Growth characteristics and cytoskeletal organization of cultured smooth muscle cells from human primary stenosing and restenosing lesions.

Growth characteristics of human plaque cells selectively extracted from advanced primary stenosing and fresh restenosing lesions by percutaneous transluminal atherectomy were studied in vitro. Cells were isolated either by explant technique or by enzymatic disaggregation, and they were identified as smooth muscle cells (SMC) by positive reaction with antibodies against alpha-smooth muscle actin. Endothelial cells were not found in the atherectomized tissue. The cells of primary stenosing tissue (ps-SMC) exhibited a significantly low growth rate (0.16 +/- 0.04 population doublings per day) in comparison to the cells of restenosing lesions (re-SMC, 0.64 +/- 0.15 population doublings per day). Furthermore, ps-SMC became senescent and remained quiescent after two passages, whereas re-SMC retained a high proliferative activity and became quiescent by passage 8 to 10. Both types of cells responded to increasing serum concentrations in a dose-dependent manner. Ps-SMC failed to respond to purified platelet-derived growth factor (PDGF) and a mitogen mixture isolated from bovine brain (ECGF), but their proliferative activity was increased by the addition of re-SMC-conditioned culture medium. Despite their high basic growth rate, the proliferative activity of re-SMC was significantly stimulated by PDGF and ECGF in a dose-dependent manner. PS-SMC and re-SMC populations consisted of two distinct subpopulations, which could be discriminated by cell size measurements and cell adhesion: 1) relatively small (cell diameter, 18.6 +/- 5 microns), low-adhesive, predominant cells, and 2) enlarged (cell diameter, 27.1 +/- 3 microns), high-adhesive, fibroblast-like cells with abundant microfilaments. Neither ps-SMC or re-SMC stained with antibodies against desmin, but did express vimentin. The organization patterns of vimentin and tubulin were unaltered in comparison to each other and to smooth muscle cells cultured from the media of nonatherosclerotic human arteries.

Orientation of Cultured Arterial Smooth Muscle Cells Growing on Cyclically Stretched Substrates

Arterial smooth muscle cells from rabbit aortic media were grown in first subcultures on hydrophilized and collagen-coated silicone membranes which were then subjected to directional cyclic stretches and relaxations at a frequency of 50 times/min. The membranes were stretched 2, 5 and 10% beyond their resting length. Cells on unstretched and stationary membranes in the same chamber served as controls. The cells which were stretched with an amplitude of 2% remained in random orientation after 14 days of continuously performed cyclic stretching. The cells which were stretched 5% for 12 days orientated at an angle of 61 +/- 9 degrees to the direction of stretching, while the cells which were stretched with an amplitude of 10% for 6 days orientated at an angle of 76 +/- 5 degrees. The cells on the stationary and unstretched membranes remained in random orientation. We were able to confirm that the angle of orientation is reversible, i.e. preorientated cells changed their orientation during application of another stretching amplitude. The results suggest that stretching of the artery wall by blood pulsation may be a factor influencing the orientation of smooth muscle cells within the media of the artery wall and of those smooth muscle cells which proliferate into the subendothelial space after mechanical injury of the endothelium or electrical stimulation of the artery wall. An apparatus is presented which produces cyclic and directional mechanical stimuli similar to those which may occur in the artery wall.

Migration of transformed renal epithelial cells is regulated by K+ channel modulation of actin cytoskeleton and cell volume.

Abstract Migration of transformed renal epithelial (MDCK-F) cells depends on the polarized activity of a Ca2+-sensitive K+ channel (IK channel; Pflügers Arch 432:R87–R93, 1996). This study was aimed at elucidating the functional link between the IK channel and the actin cytoskeleton which is required for cell locomotion. We monitored migration of MDCK-F cells with video microscopy, quantified filamentous actin with phalloidin binding, and measured the intracellular Ca2+ concentration ([Ca2+]i) with the fluorescent dye fura-2/AM. We compared the effects of IK channel activation or inhibition with those of hypotonic swelling or hypertonic shrinkage. IK channel inhibition with charybdotoxin (CTX) or cell swelling (omission of up to 50 mmol/l NaCl) as well as IK channel activation with 1-ethyl-2-benzimidazolinone (1-EBIO) or cell shrinkage (addition of up to 100 mmol/l mannitol) reduce the rate of migration dose-dependently by up to 80%, i.e., to the same extent as cytochalasin D. Inhibition of migration is accompanied either by actin depolymerization (CTX and cell swelling) or by actin polymerization (1-EBIO and cell shrinkage). Changes of migration and phalloidin binding induced by CTX and cell swelling or by 1-EBIO and cell shrinkage, respectively, are linearly correlated with each other. CTX and cell swelling elicit a rise of [Ca2+]i whereas 1-EBIO and cell shrinkage induce a slight decrease of [Ca2+]i in most MDCK-F cells. Taken together IK-channel-dependent perturbations of cell volume and anisotonicity elicit virtually identical effects on migration, actin filaments and [Ca2+]i. We therefore suggest that cell volume – possibly via [Ca2+]i– is the link between IK channel activity, actin filaments and migration. We propose a model for how temporal and local changes of cell volume can support the migration of MDCK-F cells.

Azo dyes and carcinogenic aromatic amines in cell cultures

Abstract Azo dyes are widely used in the food, pharmaceutical, cosmetic, textile and leather industries. They can be reduced by azoreductases in intestinal bacteria, liver cells and skin surface microflora so that aromatic amines are released. In this study an analytical system for the determination of carcinogenic aromatic amines at the picogram to femtogram level and a cell culture assay to evaluate the toxicological effects of azo dyes and aromatic amines is presented. For the assays, the commercial azo dye Resacor Blue 2F (Color Index: Direct Blue 15), a 3,3′-dimethoxybenzidine-based dye, was used. The released carcinogenic aromatic amine, 3,3′-dimethoxybenzidine, was extracted with diethylether derivatized with pentafluoropropionic anhydride and analyzed by capillary gas chromatography/mass spectrometry. In addition, the cytotoxicity of Resacor Blue 2F on cultured kidney epithelial cells and on two hepatocyte cell lines (Hep G2 and Chang liver) was evaluated. For this purpose, the cells were exposed for 72 h to varying concentrations of Resacor Blue 2F. The results show that the azo dye inhibits the proliferation of the kidney epithelial cells much more than the proliferation of the two hepatocyte cell lines. As calculated from the dose-response curves, the EC50 (effective concentration reducing cell proliferation by 50%) for kidney epithelial cells was 40 μg/ml, whereas the EC50 for both hepatocyte cell lines was more than 250 μg/ml. Higher concentrations of 3,3′-dimethoxybenzidine were found in kidney epithelial and in Hep G2 culture supernatants; only small amounts were found in the Chang liver culture supernatant. In summary, it was demonstrated that released 3,3′-dimethoxybenzidine was found in the cell culture supernatants, but it did not accumulate within the cells. For an interpretation of the toxicological results, cell-specific transport systems and osmotic effects of the commercial azo dye which contains several inorganic and organic additives has to be considered.

Corticosteroid agents inhibit proliferation of smooth muscle cells from human atherosclerotic arteries in vitro.

We studied the in vitro effect of steroid agents on smooth muscle cells from human atherosclerotic arteries. Recent advances in the understanding of the biology of restenosis indicate that restenosis is predominantly caused by a multifactorial stimulation of smooth muscle cell proliferation. Primary stenosing plaque material of 24 patients (aged 63 +/- 14 years) and restenosing plaque material of 7 patients (aged 65 +/- 9 years) was selectively extracted from femoral arteries by the Simpson atherectomy device. Cells were isolated by enzymatic disaggregation and identified as smooth muscle cells by positive reaction with smooth muscle alpha-actin. The steroid agents prednisolone (0.0075-750 micrograms/ml), hydrocortisone (0.0125-1250 micrograms/ml), and dexamethasone (0.0004-40 micrograms/ml) were added to the cultures. Six days after seeding the cells were trypsinized and the cell number was measured by a cell counter. All three steroid agents exhibited a significant antiproliferative effect on smooth muscle cell proliferation. At high concentrations of hydrocortisone, cytoskeletal elements of smooth muscle cells such as actin, microtubules, and vimentin, were largely altered. Our data indicate that the proliferation of smooth muscle cells from human atherosclerotic arteries in vitro can be inhibited by steroid agents and thus may open the way for local post-angioplasty treatment strategies.

Responses of cultured smooth muscle cells from human nonatherosclerotic arteries and primary stenosing lesions after photoradiation: Implications for photodynamic therapy of vascular stenoses

Cultured smooth muscle cells from human nonatherosclerotic arteries and from primary stenosing lesions were labeled with dihematoporphyrinester and ether, a photosensitizing probe used mainly for the detection and photodynamic therapy of tumors. After labeling for 24 h, cells were irradiated with ultraviolet light (wavelength 365 nm, energy densities ranging from 30 to 1,200 mJ/cm2). Twenty-four hours after photoradiation, 80% of smooth muscle cells from nonatherosclerotic arteries and only 20% of smooth muscle cells from atherosclerotic plaques were viable and still adherent. Moreover, dynamic cell and cytoskeletal alterations in response to irradiation are described. The differential sensitivity of smooth muscle cells from nonatherosclerotic arteries and from atherosclerotic plaques provides evidence that a photodynamic treatment might be a valuable therapeutic approach to vascular stenosis.

In vitro growth characteristics of human atherosclerotic plaque cells: Comparison of cells from primary stenosing and restenosing lesions of peripheral and coronary arteries

SummaryCell size distribution and growth rates were studied in vitro in human plaque cells from advanced primary stenosing and fresh restenosing lesions of peripheral and coronary arteries. Cells were isolated either by the explant technique or by enzymatic disaggregation and were identified as smooth muscle cells by their typical growth pattern and their positive reaction with antibodies against smooth muscle α-actin. Endothelial cells were found in plaque specimens from coronary arteries but were only present in primary cultures. Smooth muscle cells from primary stenosing tissue (ps-SMC) exhibited a significantly lower growth rate in culture (0.15±0.04 population doublings per day;

Differential effect of Photofrin II on growth of human smooth muscle cells from nonatherosclerotic arteries and atheromatous plaques in vitro.

\bar x \pm SD