Co-cultivation of vascular endothelial and smooth muscle cells using microcarrier techniques

DNA microarray study on gene expression profiles in co-cultured endothelial and smooth muscle cells in response to 4- and 24-h shear stress

Shear stress, a major hemodynamic force acting on the vessel wall, plays an important role in physiological processes such as cell growth, differentiation, remodelling, metabolism, morphology, and gene expression. We investigated the effect of shear stress on gene expression profiles in co-cultured vascular endothelial cells (ECs) and smooth muscle cells (SMCs). Human aortic ECs were cultured as a confluent monolayer on top of confluent human aortic SMCs, and the EC side of the co-culture was exposed to a laminar shear stress of 12 dyn/cm(2) for 4 or 24 h. After shearing, the ECs and SMCs were separated and RNA was extracted from the cells. The RNA samples were labelled and hybridized with cDNA array slides that contained 8694 genes. Statistical analysis showed that shear stress caused the differential expression (p < or = 0.05) of a total of 1151 genes in ECs and SMCs. In the co-cultured ECs, shear stress caused the up-regulation of 403 genes and down-regulation of 470. In the co-cultured SMCs, shear stress caused the up-regulation of 152 genes and down-regulation of 126 genes. These results provide new information on the gene expression profile and its potential functional consequences in co-cultured ECs and SMCs exposed to a physiological level of laminar shear stress. Although the effects of shear stress on gene expression in monocultured and co-cultured EC are generally similar, the response of some genes to shear stress is opposite between these two types of culture (e.g., ICAM-1 is up-regulated in monoculture and down-regulated in co-culture), which strongly indicates that EC-SMC interactions affect EC responses to shear stress.

Endothelial cells provide feedback control for vascular remodeling through a mechanosensitive autocrine TGF-beta signaling pathway

Mechanical forces are potent modulators of the growth and hypertrophy of vascular cells. We examined the molecular mechanisms through which mechanical force and hypertension modulate endothelial cell regulation of vascular homeostasis. Exposure to mechanical strain increased the paracrine inhibition of vascular smooth muscle cells (VSMCs) by endothelial cells. Mechanical strain stimulated the production of perlecan and heparan sulfate glycosaminoglycans by endothelial cells. By inhibiting the expression of perlecan with an antisense vector we demonstrated that perlecan was essential to the strain-mediated effects on endothelial cell growth control. Mechanical regulation of perlecan expression in endothelial cells was governed by a mechanotransduction pathway requiring autocrine transforming growth factor beta (TGF-beta) signaling and intracellular signaling through the ERK pathway. Immunohistochemical staining of the aortae of spontaneously hypertensive rats demonstrated strong correlations between endothelial TGF-beta, phosphorylated signaling intermediates, and arterial thickening. Further, studies on ex vivo arteries exposed to varying levels of pressure demonstrated that ERK and TGF-beta signaling were required for pressure-induced upregulation of endothelial HSPG. Our findings suggest a novel feedback control mechanism in which net arterial remodeling to hemodynamic forces is controlled by a dynamic interplay between growth stimulatory signals from VSMCs and growth inhibitory signals from endothelial cells.

Co-culture of endothelial cells and smooth muscle cells affects gene expression of angiogenic factors

Endothelial cells (EC) are in contact with the underlying smooth muscle cells (SMC). The interactions between EC and SMC in the vessel wall are considered to be involved in the control of growth and function of blood vessels. A co-culture system of EC and SMC and a method for separation of these cells was developed in order to investigate whether the presence of physical contact between EC and SMC affected the gene expression of angiogenic factors. Human EC and SMC were prepared from the great saphenous veins. Autologous EC were added on top of the confluent layer of SMC. After 72 h in co-culture, the EC were magnetically separated from SMC with the use of superparamagnetic beads. RT-PCR products for bFGF, bFGFR, VEGF, PDGF-AA, PDGF-BB, TGF-beta, and beta-actin were analyzed to study the mRNA expressions. The protein level of selected factors was studied by ELISA technique. In co-cultured SMC there was a statistically significant higher gene expression of VEGF, PDGF-AA, PDGF-BB, and TGF-beta and significant lower gene expression of bFGF and its receptor than in single cultured SMC. The protein level of PDGF-BB and TGF-beta was also significantly higher in co-cultured SMC. In co-cultured EC there were no significant differences in gene expression of PDGF-AA, PDGF-BB, and TGF-beta compared with single cultured EC. The gene expression and protein synthesis of VEGF was significantly higher in co-cultured EC. The findings from the present study suggest that cell-cell interactions of EC and SMC affect the gene and protein expression of angiogenic factors.

Correlating the kinetics of cytokine-induced E-selectin adhesion and expression on endothelial cells

Many human diseases are mediated through the immune system. In chronic inflammatory disorders, the processes ordinarily involved in tissue healing become destructive. Endothelial cells normally recruit leukocytes to inflamed tissue using cytokine-induced adhesion receptors on the surfaces of interacting cells. Leukocyte capture depends on specialized characteristics of these receptors, particularly the binding kinetics. This study is designed to clarify the relationship between cytokine-induced changes in cell properties and binding kinetics. Here, we measure the kinetics of expression and monoclonal antibody binding for E-selectin in interleukin-1alpha-stimulated microvascular endothelium in vitro and incorporate the data into kinetic models. Quantitative flow cytometry is used to determine molecular density (expression), and micropipette assays are used to find the probability of adhesion (function). Within five hours of interleukin-1alpha stimulation, E-selectin density increases from 0 to 742 sites/microm(2), and antibody-E-selectin adhesion probability increases from a baseline of 6.3% to 64%. A kinetic model is applied to find an apparent association rate constant, k(f), of 3.7 x 10(-14) cm(2)/sec for antibody-E-selectin binding. Although the model successfully predicts experimental results, the rate constant is undervalued for a diffusion-limited process, suggesting that functional adhesion may be modified through cytokine-induced changes in microtopology and receptor localization.

Endothelial heparan sulfate is necessary but not sufficient for control of vascular smooth muscle cell growth

The state of the endothelial cell (EC) determines the nature of its control of vascular smooth muscle cell (vSMC) biology. Conditioned medium from postconfluent ECs inhibits vSMC proliferation, whereas subconfluent conditioned medium from the same ECs has a stimulatory effect. We and others have identified confluent endothelial cells' production of heparan sulfate proteoglycans (HSPG) as critical to vSMC growth control. The question that arises is whether the stimulation that is observed with subconfluent cells is from (1) aberrant HSPG production, (2) elaboration of noninhibitory species of HSPG, or (3) production of other factors, such as mitogens, which counteract the inhibitory HSPG to stimulate vSMCs. We studied the relative effects of conditioned medium produced by both subconfluent and postconfluent EC cultures on vSMC growth. Conditioned medium was fractionated into nonproteoglycan (non-PG) and proteoglycan (PG) components by anion-exchange chromatography. The PG fractionation profile and the antiproliferative activity of the HSPGs isolated from both subconfluent and postconfluent EC-conditioned media were similar. However, the HSPG fraction alone could not approach the inhibitory potential of unfractionated conditioned medium from postconfluent EC cultures. Non-PG proteins produced by the endothelial cultures had no effect on vSMC growth on their own. Yet, when they were mixed together with HSPG fractions, from either subconfluent or postconfluent EC cultures, the full growth effects were returned. Non-PG protein fractions from postconfluent cultures with HSPG fractions gave maximal inhibition of vSMC growth, whereas non-PG protein fractions from subconfluent EC cultures with HSPG fractions produced the maximal stimulation. Thus, whereas the net stimulatory or inhibitory effect on vSMC growth of EC-conditioned medium is density dependent, this effect does not result from a difference in the antiproliferative heparan sulfate component but rather from non-PG proteins that interact with the heparan sulfates.

Fibroblast growth factor-2-toxin induced cytotoxicity: differential sensitivity of co-cultured vascular smooth muscle cells and endothelial cells

Recombinant FGF-2-SAP is a mitotoxin consisting of the plant-derived ribosome-inactivating toxin saporin (SAP) fused to basic fibroblast growth factor (FGF-2). FGF-2-SAP targets and kills cells bearing upregulated FGF receptors. In vivo, FGF-2-SAP inhibits smooth muscle cell hyperplasia in models of restenosis. The present study examined the potential for a differential effect of FGF-2-SAP on canine vascular endothelial cells (EC) and smooth muscle cells (SMC) separately as well as in a novel co-culture model. Canine vascular SMC and EC cultures were established separately and made quiescent once cells reached 80% confluence. Following the release from growth arrest, both cell types were treated with FGF-2-SAP, or FGF-2, or SAP alone for 48 h. [3H]TdR incorporation was used to determine the growth response of SMC and EC. The co-culture system was created by plating canine vascular SMC and EC on either side of a microporous 13 microm thick polyester membrane insert. Both cell types were grown to 80% confluence and independently made quiescent. Following the release from growth arrest, cells were treated with FGF-2-SAP, or FGF-2, or SAP alone. Negative and positive control groups were untreated wells containing phosphate buffered saline and complete growth media, respectively. After 48 h, both [3H]TdR incorporation and total DNA content, by fluorometric measurement, were quantitated in SMC and EC independently. FGF-2-SAP showed a concentration-dependent cytotoxicity in both canine SMC and EC but cytotoxicity for EC required substantially higher concentrations. In co-cultured SMC, FGF-2-SAP significantly decreased both [3H]TdR uptake and total DNA content at 0.5, 5, 50, and 500 ng/ml (0.01-10 nM) compared to positive controls. In co-cultured EC, FGF-2-SAP decreased [3H]TdR uptake at 50 and 500 ng/ml and total DNA content at 500 ng/ml compared to positive controls. Neither SAP alone nor FGF-2 alone showed a significant effect on [3H]TdR uptake or DNA content of either SMC or EC. In this unique co-culture model, which better replicates the relationship between SMC and EC in vivo, we demonstrated a dose-response range of FGF-2-SAP at which both the proliferation and total cell number of SMC, but not EC, is significantly reduced. These data suggest that FGF-2-SAP may have therapeutic utility in inhibiting myointimal hyperplasia in the absence of a deleterious effect on regenerating endothelium following vascular reconstructions.

Smooth muscle cell proliferation in response to co-culture with venous and arterial endothelial cells

PURPOSE

The critical role of endothelial cells (ECs) in arterial disease is well established, but little is known of their role in venous disease. Previous studies suggest inherent differences between arteries and veins: arterial stenoses demonstrate a large lipid component, whereas hemodialysis-related venous stenoses are characterized by marked smooth muscle cell (SMC) proliferation. This study compares effects of venous versus arterial ECs on SMC proliferation in co-culture.

MATERIALS AND METHODS

Human saphenous vein ECs (HSV-ECs) or human aortic ECs (HA-ECs) were cultured on the underside of 10-micron, porous polycarbonate membranes and allowed to grow to confluence for 48 hours. After EC confluence, human aortic SMCs (HA-SMCs) were cultured on the membranes opposite the EC (day 0). On days 0, 1, 2, 4, 6, and 8, membranes were harvested (n = 3 per day), stained with Hoechst dye, and HA-SMCs were counted by fluorescence microscopy. Controls were HA-SMCs cultured alone. Comparisons were made by two-way multivariate analysis of variance.

RESULTS

During the entire 8-day period, there was significant induction of HA-SMC proliferation by both HSV-ECs (P = .0003) and HA-ECs (P = .0012). Maximal inductions were 88% +/- 11% for HSV-ECs (P = .0015) and 24% +/- 6% for HA-ECs (P = .0015). HSV-ECs exhibited a three- to ninefold greater induction than HA-ECs (P = .0003).

CONCLUSION

HSV-ECs induce adjacent HA-SMC proliferation, possibly in a paracrine manner to a significantly greater extent than HA-ECs.

Coculture of endothelial cells and smooth muscle cells in bilayer and conditioned media models

Smooth muscle cell (SMC) growth characteristics are affected by endothelial cells (ECs) in vivo and in vitro. In this study, we compare a bilayer EC/SMC coculture model that allows cell contact with a model of SMCs growing in media continuously conditioned by ECs, but without physical contact. Bovine aortic SMCs were plated on one side of a 13-microns-thick, semipermeable membrane. Three models were compared: (1) SMCs cultured alone (with no cells on the opposite side of the membrane, O/SMC); (2) SMCs cultured with ECs on the opposite side of the membrane in a bilayer coculture system that allows physical contact between ECs and SMCs (EC/SMC); and (3) SMCs cultured in media continuously conditioned by adjacent ECs, without contact (conditioned media, CM). After cultures were established, SMCs were harvested at 7 and 14 days after plating (n = 5 cultures/day/group). SMC DNA and protein content and [3H]thymidine incorporation were measured in each group. On Days 7 and 14 after plating, ECs in both the EC/SMC and CM models stimulated SMC proliferation > 50% compared to O/SMC controls (P < 0.05). SMC density was similar for the EC/ SMC and CM models at Day 7, but SMC density was higher in the EC/SMC group at Day 14 in culture (P < 0.05). At Day 7, protein synthesis was similar in the three groups, but by Day 14, SMCs in the EC/SMC group had produced significantly less cellular protein/ DNA than SMCs in the CM group (P < 0.05), which in turn had less protein/DNA than the control (O/SMC) group (P < 0.05). SMCs in the EC/SMC and CM groups retained a thin, spindle shape with filamentous projections, compared to the hypertrophic appearance of SMCs in the absence of ECs. Electron microscopy revealed projections from SMCs which traversed the pores in the coculture membrane and made intimate contact with ECs. The degree of EC/SMC contact increased from 7 to 14 days (P < 0.05). Compared to SMCs alone, ECs in bilayer coculture or conditioned media altered SMCs growth characteristics similarly after 7 days in culture. By 14 days, however, the bilayer coculture had a significantly greater effect on SMC density and protein synthesis. The bilayer model is unique in terms of luminal/abluminal orientation of the cells, the proximity of the cell layers, and the presence of physical cell contact. Since the bilayer model amplifies the effect of ECs on SMCs, it may be more useful than conditioned media to study EC-SMC interactions.

Proliferation of smooth muscle cells in the inner and outer layers of the tunica media of arteries: an in vitro study

During the development of atherosclerotic and fibromuscular proliferates/lesions, smooth muscle cells (SMC) in the media, particularly near the lumen, are activated to migrate into the intima, where they continue to proliferate to form an intimal thickening. It is to date unclear whether SMCs situated adjacent to the adventitia possess a lower capacity to proliferate because they are a special subpopulation of medial SMCs or because the adventitia excerts an inhibitory effect. We have, therefore, developed an in vitro system whereby we have attempted to clear up this uncertainty. The following observations were made from the in vitro experiments: Media-explants from rabbit aorta were laid on a polycarbonate filter with pores 5 microns in diameter. The SMCs migrated through the pores and formed a fibromuscular proliferate on the other side of the filter. Endothelial cells were seeded on one side of the filter before media-explants were laid on the other side of the filter. The confluent endothelium inhibited migration of SMCs through the filter pores. Media-explants were placed between two polycarbonate filters (pores 5 microns diameter). In this "sandwich" arrangement SMCs migrated through both filters, i.e., in both directions. The quantity of migrating and proliferating cells through both filters was almost identical. This suggests that there is no difference in the migratory and proliferative capacity of SMCs in the inner and outer layers in the media of arteries. To investigate the influence of the adventitia on medial SMCs, media-explants were placed between a lower (5 microns) and an upper (0.2 micron) filter. On the 0.2 micron filter adventitia-explants were laid above the media-explants. The 0.2 micron filter prevented migration of SMCs from the media-explant into the adventitia and migration of fibroblasts from the adventitia into the media. Interestingly, the adventitial tissue inhibited proliferation of SMCs at the abluminal and migration and proliferation at the luminal side of the media-explant; the number of cells migrating through the 5 microns pores at the luminal side was diminished, suggesting that the adventitial tissue has an antiproliferative influence on SMCs. Moreover, it was found that in media-explants near the filter with adventitia, the medial SMCs were in a better preserved condition than at the de-endothelialised luminal side. As a control, cultures consisting of media-explants were incubated without filters (i.e., explant organ cultures). The proliferates in the concavity (luminal side) exhibited a pattern of proliferating SMCs different from that of the cells at the abluminal convexity.(ABSTRACT TRUNCATED AT 400 WORDS)

Aortic endothelial and smooth muscle cell co-culture: an in vitro model of the arterial wall

Interactions between vascular endothelial (EC) and smooth muscle cells (SMC) contribute both to the normal function of the vascular wall and to the pathogenesis of lesions such as atherosclerosis and fibrointimal hyperplasia. However, study of these interactions has been hampered by the difficulty in growing these two cell types in simultaneous culture. Methods using conditioned media, shared media, and bilayer culture have been described, but none is well suited to the study of vascular cell interactions. We report a method for EC-SMC co-culture that preserves bilayer morphology, allows independent study of the cells and their matrices after intervention, remains stable over long periods in culture, and permits study of changes in cell-cell interaction with growth of the cells to confluence. This simple bilayer co-culture system simulates the in vivo situation and may enhance our understanding of EC-SMC interactions.

Effects of co-culture with vascular endothelial cells on the renin-like enzyme production in vascular smooth muscle cells

Cultured human vascular smooth muscle cells (VSMC) produced an immunologically specific renin-like enzyme. The production of the renin-like enzyme was increased by 1 mM N6-O2'-dibutyryladenosine 3',5' cyclic monophosphoric acid sodium salt (db-cAMP). When co-cultured with human vascular endothelial cells (EC) and human skin fibroblast (FB), the basal production of the renin-like enzyme was increased. And the extent of the increase by db-cAMP was amplified by co-culture with EC, but not by the co-culture with FB.

Endothelium-derived relaxing factor in cultured cells

Many vasoactive agents stimulate release of an endothelium-derived relaxing factor (EDRF). EDRF stimulates cyclic guanosine 3',5'-monophosphate (cGMP) accumulation and relaxation of vascular smooth muscle in a manner similar to that produced by sodium nitroprusside. Endothelium and vascular smooth muscle were isolated from porcine, bovine, and rat thoracic aorta. The capacity of sodium nitroprusside to stimulate cGMP accumulation in cultured bovine, porcine, and rat vascular smooth muscle was found to increase with time in culture to a maximum of 12 to 14 days after plating. In addition, bovine and porcine vascular smooth muscle, but not rat vascular smooth muscle, lost the sodium nitroprusside-stimulated cGMP response after the fifth passage. Cultured endothelial cells did not respond to endothelium-dependent vasodilators or sodium nitroprusside with increased cGMP levels. Vascular smooth muscle cells responded only to sodium nitroprusside. Mixed cultures of porcine and bovine endothelium and vascular smooth muscle and bovine endothelium and rat vascular smooth muscle responded to endothelium-dependent vasodilators with increased cGMP levels. Short-term (4 hours) coculture experiments using bovine endothelium grown on microcarriers to assess the need for long-term contact between the two cell types produced similar results. Release of EDRF from bovine endothelium was studied by loading endothelium-covered microcarrier beads into a column superfused with physiological buffer. Treatment of the column with bradykinin, the calcium ionophore A23187, melittin, and arachidonate released EDRF from the column as measured by cGMP changes in denuded aortic rings and vascular smooth muscle cells and by relaxation of rings when bathed in column effluent. The time course of cGMP changes and relaxation were similar and could be reversed by hydroquinone.(ABSTRACT TRUNCATED AT 250 WORDS)

Growth and analysis of vascular smooth muscle on microspheres

Protocols for culturing vascular smooth muscle cells (VSMCs) on polystyrene microspheres, assessing VSMC contractility while adhered to the microspheres, and analyzing VSMCs cultured on microspheres by flow cytometry are described. These procedures preserve optimal VSMC viability and function, while providing a method for assessing these cells within the parameters required for analysis by flow cytometry.

Short- and long-term interactions of endothelium and vascular smooth muscle in coculture: effects on cyclic GMP production

In intact blood vessels, many vasodilators act by stimulating the release from endothelium of factor(s) that relax vascular smooth muscle and stimulate increases in cGMP. To investigate how endothelium regulates cGMP production in vascular smooth muscle, bovine aortic endothelial cells and rat aortic smooth muscle cells were cultured both separately and together in cocultures for 48 hr. Nitroprusside (1 mM) increased intracellular cGMP concentration 30-fold in smooth muscle cells (from a basal level of 103 +/- 54 fmol/mg of cell protein to 2920 +/- 1800 fmol/mg) but only 2-fold in endothelial cells (from 41 +/- 7 fmol/mg to 93 +/- 23 fmol/mg). When endothelial and smooth muscle cells were cocultured as a mixed cell population (1:1 cell ratio), both basal and nitroprusside-stimulated cGMP levels were significantly increased (550 +/- 250 and 13,240 +/- 9950 fmol/mg of total cell protein, respectively). The calcium ionophore A23187 (10 microM) caused no increase in cGMP concentration in either cell type cultured alone but produced a 6-fold increase in cocultures. Neither aspirin nor 5,8,11,14-icosatetraynoic acid influenced these results. No changes in cAMP levels were detected. Using cocultures in which one cell type was grown on microcarrier beads, we have shown that cGMP increased only in vascular smooth muscle cells and was not dependent upon the formation of junctions between endothelium and smooth muscle cells. In long-term (48-hr) mixed-cell cocultures, but not in short-term microcarrier cocultures, amplification of the nitroprusside-induced increase in cGMP was observed. These results show that responses associated with endothelium-dependent relaxation can be reconstituted in cultured endothelial and vascular smooth muscle cells and that endothelium generates a humoral factor(s) that stimulates accumulation of smooth muscle cGMP and has a longer-term effect that amplifies guanylate cyclase stimulation by nitroprusside, a drug acting directly upon smooth muscle to stimulate formation of the cyclic nucleotide. Cultured cells provide a valuable model system for the study of endothelium-vascular smooth muscle interactions.

Co-cultivation of astroglial and neuronal primary cultures from rat brain

A technique is described for a two-cell co-cultivation system which permits in vitro evaluation of neuron-glia interactions. Primary astroglial enriched cultures from newborn rat cerebral hemispheres, striatum or cerebral cortex, grown for 3 days, were co-cultivated with primary neuron-containing cultures from 15- to 17-day rat embryo cerebral hemispheres, substantia nigra or brainstem, respectively, grown for 10 days on polylysine-coated surfaces. The neuronal cells were identified morphologically and immunohistochemically by antibodies to neuron-specific enolase. The two cultures were grown together for 7 days, separated by a U-formed 1 mm glass-rod. The results show that neurons exert a morphogenetic effect on astroglial cells in the form of extension of cell processes. The co-culture system allows investigation of potent local humoral interactions between astroglial cells and neurons.

Reconstitution of the vascular wall in vitro. A novel model to study interactions between endothelial and smooth muscle cells

To study the biology of the endothelium under conditions that mimic the architecture of the vessel wall, endothelial cells were grown on a collagen lattice containing a multilayer of smooth muscle cells. Light and electron microscopy of such cultures revealed a confluent monolayer of flattened endothelial cells. In co-culture, endothelial cells tend to elongate, whereas in the absence of smooth muscle cells, the endothelial cells show the polygonal morphology typical for cultures of endothelial cells grown on polystyrene substrates. As conditioned culture media of endothelial cells contain substances that may both promote or inhibit the growth of smooth muscle cells, the availability of this vessel wall model prompted us to examine to what extent endothelial cells regulate the proliferation of smooth muscle cells when these cells are maintained in co-culture. Here we show that endothelial cells suppress the proliferation of co-existing smooth muscle cells. This finding suggests that under physiological conditions the balance of the action of growth-promoting and growth-inhibiting substances produced by endothelial cells is in favour of the latter.

Cultured endothelial cells do not respond to a platelet-derived growth-factor-like protein in an autocrine manner

Cultured endothelial cells produce a growth factor similar or identical to platelet-derived growth factor (PDGF). Endothelial cells are able to proliferate in plasma-supplemented medium, while most nontransformed cells require serum-supplemented medium. Since PDGF is a major serum mitogen, we have tested the possibility that endothelial cells interact with and respond to the autologously produced PDGF-like (PDGF-c) protein. We have found that bovine aortic and rat heart endothelial cells express little or no cell surface PDGF receptors as determined by binding of pure 125I-PDGF. Treating these cells under acidic conditions, which release receptor-bound PDGF in control cells without affecting receptor function, did not reveal a population of cryptic receptors. In addition, when rat heart endothelial cells were grown in the presence of an antibody to PDGF, proliferation was unimpaired, though no detectable free PDGF was present in the medium. An equivalent amount of antibody completely blocked the mitogenic response of human fibroblasts that had been preincubated for 1 h at 37 degrees C with an equivalent dose of PDGF. Thus, endothelial cells do not respond mitogenically in a manner that would be expected from the interaction of autologously produced PDGF with its cell surface receptor. Endothelial cells were detergent-solubilized and immobilized on nitrocellulose in an attempt to detect the presence of intracellular PDGF receptors. Specific binding of 125I-PDGF to adsorbed, solubilized bovine aortic or rat heart endothelial cells was undetectable, though significant binding to adsorbed, solubilized fibroblasts, used as a positive control, was observed. We conclude that endothelial cells do not have detectable intracellular PDGF receptors.

Evidence for endothelium-derived relaxing factor in cultured cells

Intracellular cyclic GMP concentration was used as a biochemical indicator of endothelium-dependent and organonitrate-induced responses to these vasodilators in cultured porcine aortic smooth muscle and endothelial cells. Sodium nitroprusside (10(-6) M) caused a rapid increase in cyclic GMP levels in confluent smooth muscle cell cultures but not in confluent endothelial monolayers. Adenosine triphosphate (10(-4) M) and methacholine (10(-5) M), two agents that elicit endothelium-dependent relaxation in intact vessels, failed to raise cyclic GMP concentrations in muscle or endothelial cultures alone. When the cell types were grown together in mixed culture, however, treatment with adenosine triphosphate or methacholine induced an elevation in intracellular cyclic GMP levels. These findings suggest that mixed cultures of arterial smooth muscle and endothelial cells can be used to study the phenomenon of endothelium-dependent responses in arterial smooth muscle.

Metabolic cooperation between vascular endothelial cells and smooth muscle cells in co-culture: changes in low density lipoprotein metabolism

A microcarrier co-culture system for aortic endothelial cells and smooth muscle cells (SMCs) was developed as a model for metabolic interactions between cells of the vessel wall. Low density lipoprotein (LDL) metabolism in SMCs was significantly influenced by co-culture with endothelium. The numbers of high affinity receptors for LDL was increased more than twofold (range, 2.1-5.6), with concomitant increases in LDL receptor-mediated endocytosis and degradation. These effects reached a plateau at an endothelial cell/SMC ratio of 1. Kinetic analysis of the endocytic pathway for LDL in SMCs indicated that, in co-culture with endothelium, there was no alteration in the binding affinity of LDL to its receptors but that the internalization rate constant declined and the rate constant for degradation increased. This analysis suggested that the formation and migration of endocytic vesicles was the rate-limiting step of enhanced LDL metabolism under co-culture conditions. Two mechanisms by which endothelial cells influenced smooth muscle LDL metabolism were identified. First, mitogen(s) derived from endothelial cells stimulated entry of SMCs into the growth cycle, and the changes in LDL metabolism occurred as a consequence of G1-S transition. Second, SMC lipoprotein metabolism was stimulated in the absence of mitogens by a low molecular weight (less than 3,500) factor or factors. Co-culture was a required condition for the latter effect, suggesting that the mediator(s) may be unstable or that cell-cell communication was necessary for expression. These results (a) demonstrate that vascular cell interactions can modify LDL metabolism in SMCs, (b) provide some insights into the mechanisms responsible, and (c) identify co-culture as an experimental approach appropriate to certain aspects of vascular cell biology.

Effect of chronic denervation on pharmacological responsiveness of coronary vessels

We have hypothesized that the well-established regional heterogeneity of the properties of the vascular smooth muscle results from peculiarities of the microenvironment in every region. In particular, the coronary vasculature has well-established differences between large and small coronary arteries in their responsiveness to alpha and beta agonists, nitroglycerin and adenosine. To test our hypothesis, we altered the micro-environment of coronary vessels by chronic surgical sympathectomy in dogs. Our in vitro studies on vessels from normally innervated hearts confirmed previous studies and showed that in large vessels, alpha and beta epinephrine or norepinephrine responses can be demonstrated; the alpha effect is dominant and epinephrine is a more potent alpha agonist than is norepinephrine. In small vessels only a beta catecholamine effect can be demonstrated. Chronically sympathectomized blood vessels show an alpha norepinephrine effect in small vessels. Denervation caused a reduction in the sensitivity to K+-induced contraction in both large and small vessels. In large vessels the responses to nitroglycerin were not affected by denervation, whereas in small vessels the sensitivity to adenosine was reduced. These results indicate that chronic denervation alters the pharmacological responsiveness of the vasculature to various agonists indicating that vascular smooth muscle possesses the ability to respond to long-term modulatory influences arising in the immediate environment.

Effect of monocyte migration on low density lipoprotein transport across aortic endothelial cell monolayers

Endothelial cell monolayers on polycarbonate filters present a barrier to low density lipoprotein (LDL) and albumin transport. These cells form a relatively tight monolayer as shown by measurements of electrical resistance across the monolayer (15 omega-cm2). Monocytes are able to migrate freely across the monolayers in response to chemotactic stimuli. Monocyte chemotaxis across the monolayer caused a marked increase in LDL and albumin transport across the monolayer in the direction of monocyte migration. However, transport in the opposite direction was not significantly increased. These results suggest that monocyte migration across the endothelium could lead to an increased LDL content of the intima.

Cultured endothelial cells produce multiple growth factors for connective tissue cells

Cultured bovine aortic endothelial cells (BAEC) secrete into their medium a growth-promoting factor that stimulates many connective tissue cells in culture. We now report that this growth-promoting activity is due to at least two different proteins which are biochemically separable and immunologically distinct. Cation exchange chromatography (Carboxymethyl-Sephadex) of concentrated BAEC-conditioned medium yields two major peaks of growth-promoting activity which adsorb at pH 8 and elute with a salt gradient. One of these peaks contains as well a protein that inhibits the binding of radioiodinated platelet-derived growth factor (PDGF) to its receptor on target cells. The PDGF-like mitogen is purified approx. 25-fold by this chromatographic step. A second peak of mitogenic activity exhibits no binding to the PDGF receptor. Both the PDGF-like mitogenic activity and the PDGF-distinct mitogenic activity are highly cationic, stable to boiling, sensitive to beta-mercaptoethanol, and between 30 and 50 kD in molecular weight. Complementary studies with human umbilical vein endothelial cells in culture were performed. These human cells also produce both growth-promoting activity and a protein that binds to the PDGF receptor. The latter activity is greatly inhibited by a specific antiserum to human PDGF, whereas the growth-promoting activity of the conditioned medium is minimally affected. The degree of inhibition of the two activities is, however, quantitatively consistent: 3.5 ng of PDGF-like activity in the radioreceptor assay is inhibited, while 5 ng of PDGF-like activity in the DNA synthesis assay is inhibited. The data from the two species are consistent with the proposal that cultured endothelial cells produce at least two distinct mitogens, one of which is biochemically and immunologically related to PDGF.

Cellular proliferation in atherosclerosis and hypertension

We have tried to compare the proliferative responses seen in two vascular diseases: atherosclerosis and hypertension. Both diseases involve endothelial injury and proliferation, but our knowledge of this phenomenon is just beginning to emerge. In atherosclerosis the best evidence is that denudation does not occur in the normal young animal. Man, however, ages over a much longer time than our usual animal models, and the study of denudation during the chronic progression of atherosclerotic lesions remains to be done. We need to consider the possibility that repetitive, small lesions may occur at sites of endothelial turnover. We also need to know more about the possible role of nondenuding injuries, including death of endothelial cells in situ and the apparent increased stickiness of endothelial cells and monocytes during the early stages of hypercholesterolemia. The role of endothelial injury in hypertension also needs more study. We know that extensive denudation and thrombosis occur in small vessels subjected to high blood pressure. It is highly probable that release of PDGF occurs at these sites, possibly accounting for the characteristic hyperplasia seen in malignant hypertension. Whether this process is related to the more subtle changes in vessel wall mass seen in chronic hypertension remains unknown. Finally, there are remarkable differences in the proliferative behavior of the smooth muscle cells themselves in these two diseases. Hypertensive vascular disease is, in large part, a disease of the media. Atherosclerosis is characterized by intimal hyperplasia. Injury results in migration of smooth muscle cells from the media and cell division in the intima. It is possible to identify chemotactic factors using putative atherosclerosis risk factors or normal components of serum. This has already been done for one component of lesion formation, PDGF, and there is a report of a monocyte chemotactic factor released by smooth muscle cells. Factors released by other components of lesions may be of considerable interest. In contrast, changes in hypertension occur within a more orderly preservation of vessel wall structure. The wall thickens, but this occurs by increased synthesis of cell mass in the media. The cells themselves do not even divide, but they undergo a form of amitotic replication of their DNA.(ABSTRACT TRUNCATED AT 400 WORDS)