The response of adult human saphenous vein endothelial cells to combined pressurized pulsatile flow and cyclic strain, in vitro.

Adult human saphenous vein endothelial cells (HVEC) were cultured in a compliant tubular device and evaluated by Northern hybridization for the effects of combined pressurized pulsatile flow and cyclic strain on the expression of mRNAs for endothelin-1 (ET-1), endothelial cell nitric oxide synthase (ecNOS), tissue plasminogen activator (tPA), and plasminogen activator inhibitor type 1 (PAI-1). The hemodynamic environment was designed to mimic shear stress conditions at the distal anastomosis of a saphenous vein graft, a common site of intimal proliferation. Steady-state mRNA levels in experimental tubes were expressed relative to that in controls. No changes were observed in ET-1 mRNA after 1 and 24 hr, but a 50% decrease in experimental cultures was observed after 48 hr in the vascular simulating device. Similar results were obtained for ecNOS mRNA, although a subgroup (4 of 11) showed a significant decrease (>50%) by 24 hr. For tPA mRNA, no change was observed after 1 hr, but a significant decrease (>60%) was measured after 24 hr and no message was detectable after 48 hr. Steady-state levels for PAI-1 mRNA remained unchanged through 48 hr of treatment. These results show that pressure, pulsatile flow, and cyclic strain, when applied in concert, differentially alter vasoactive and fibrinolytic functions in HVEC. Moreover, the dramatic decrease in steady-state levels of tPA mRNA is consistent with a shift toward an increased thrombotic state.

Characteristics of vascular wall cells subjected to dynamic cyclic strain and fluid shear conditions in vitro.

We recently developed an in vitro silicone rubber tubular apparatus, the vascular simulating device (VSD), which simulates pressure, flow, and strain characteristics of peripheral arteries (Benbrahim et al., 1994, J. Vasc. Surg. 20, 184-194). In this report, we tested the ability of silicone rubber surfaces to support the growth and differentiation of endothelial cells (EC) and smooth muscle cells (SMC) and studied the effects of arterial levels of pressure, flow, and strain on these properties. Human umbilical and saphenous vein EC and bovine aortic EC and SMC were cultured on coated and uncoated silicone rubber in flat and tubular configurations (6 mm inner diameter) and on tissue culture plastic (TCP). Attachment, growth, and differentiation were compared on these surfaces. In addition, the effects of arterial pressure, flow, and strain conditions on adhesion and subsequent growth and differentiation were studied in the tubular configuration. Attachment and growth of vascular wall cells on fibronectin-coated silicone rubber was similar to that obtained on TCP. Application of arterial levels of pressure, flow, and strain did not alter adhesion of the cells to the tubes. Subsequent passage of these cells demonstrated that attachment, growth, and differentiation (uptake of LDL and expression of factor VIII-related antigen by EC and expression of muscle-specific actin by SMC) were similar in cells derived from experimental and control tubes which were not subjected to arterial conditions. Finally, mRNA expression of specific "housekeeping" genes was similar in cells isolated from experimental and control tubes. We conclude that the VSD supports the culture of viable and differentiated EC and SMC. These experiments demonstrate that it is possible to evaluate the effects of arterial strain and fluid shear on vascular wall cells in vitro, in a configuration similar to the blood vessel wall.

A compliant tubular device to study the influences of wall strain and fluid shear stress on cells of the vascular wall.

PURPOSE: Cellular constituents of the blood vessel wall are continuously subjected, in vivo, to both mechanical and hemodynamic forces, which elicit structural and biologic responses. We have developed a compliant tubular system, the vascular simulating device (VSD), that reproduces these forces, while supporting the attachment and the experimental manipulation of endothelial and smooth muscle cells. METHODS: The VSD consists of a compliant silicone rubber tube coupled to a pump system, which permits the simultaneous application of known levels of pressure and flow, to vascular wall cells cultured on the inner surface of the tube. Seeded cells can be monitored visually under phase contrast or fluorescent optics, as well as harvested and analyzed for biologic responses. RESULTS: The elastic modulus and compliance of the silicone rubber tube are similar to those of canine and human arteries. Endothelial and smooth muscle cells cultured on the lumenal surface of the tubes remain attached and viable after subjecting them to physiologic pulsatile flow and cyclic strain. CONCLUSION: The VSD makes it possible to approximate, in vitro, those forces encountered by vascular wall cells, in vivo and therefore may make it possible to determine whether specific combinations of mechanical and hemodynamic forces are causally associated with specific vascular diseases.

Dibutyryl cyclic AMP stimulates expression of ependymin mRNA and the synthesis and release of the protein into the culture medium by neuroblastoma cells (NB2a/d1).

Northern blot, immunoprecipitation, and gel electrophoretic data demonstrate that the mouse neuroblastoma NB2a/d1 cells express ependymin mRNA and synthesize and release into the culture medium a protein with immunoreactivity and electrophoretic mobility properties identical to ependymin. This is a brain extracellular glycoprotein that has been implicated in the consolidation process of memory formation and neuronal regeneration. In labeling experiments with 35S-methionine, dibutyrylcyclic3',5'-adenosine-monophosphate (dbcAMP) was found to stimulate the expression of ependymin mRNA and the enhanced synthesis and release of ependymin into the culture medium at the same time that dbcAMP stimulation of neurite outgrowth takes place. These results are consistent with the proposed role of the protein in the mechanism of neuronal regeneration and synaptogenesis. The data indicate that the NB2a/d1 cell line is a good model system for studies of the functional properties of ependymin.

Evidence for the in vivo polymerization of ependymin: a brain extracellular glycoprotein.

Ependymin, a glycoprotein of the brain extracellular fluid, has been implicated in synaptic changes associated with the consolidation process of long-term memory formation and the activity-dependent sharpening of connections of regenerating optic nerve. In vitro experiments have demonstrated that ependymin has the capacity to form fibrous insoluble polymers (FIP) when the solvent Ca2+ concentration is reduced by the addition of EGTA. Such products, once formed, do not dissolve in 2% sodium dodecyl sulfate (SDS) in 5 M urea. This property was used to develop a method for isolating brain FIP. A reproducible quantity of FIP was found in goldfish and mouse brain. This was highly concentrated in the synaptosomal fraction and had identical immunoreactivity properties to FIP obtained by the polymerization of pure ependymin in vitro as well as a cross-reactivity to other protein components of the extracellular matrix such as fibronectin and laminin. Labeling studies with [35S]methionine showed that labeled FIP aggregates are synthesized in vivo and become associated with the synaptosomal fraction. A comparison of the amino acid sequence of ependymin with those for proteins of the extracellular matrix indicated that common sequences 5-6 amino acids long exist in the molecules. These homologies may explain why antibodies to fibronectin, laminin and tubulin can recognize the FIP prepared from pure ependymin. These results suggest that ependymin can polymerize in vivo to form FIP aggregates which have similar immunoreactivity properties to major components of the brain extracellular matrix.