Involvement of myoendothelial gap junctions in the actions of endothelium-derived hyperpolarizing factor

The nature of the vasodilator endothelium-derived hyperpolarizing factor (EDHF) is controversial, putatively involving diffusible factors and/or electrotonic spread of hyperpolarization generated in the endothelium via myoendothelial gap junctions (MEGJs). In this study, we investigated the relationship between the existence of MEGJs, endothelial cell (EC) hyperpolarization, and EDHF-attributed smooth muscle cell (SMC) hyperpolarization in two different arteries: the rat mesenteric artery, where EDHF-mediated vasodilation is prominent, and the femoral artery, where there is no EDHF-dependent relaxation. In the rat mesenteric artery, stimulation of the endothelium with acetylcholine (ACh) evoked hyperpolarization of both ECs and SMCs, and characteristic pentalaminar MEGJs were found connecting the two cell layers. In contrast, in the femoral artery, ACh evoked hyperpolarization in only ECs but not in SMCs, and no MEGJs were present. Selective hyperpolarization of ECs or SMCs evoked hyperpolarization in the other cell type in the mesenteric artery but not in the femoral artery. Disruption of gap junctional coupling using the peptide Gap 27 markedly reduced the ACh-induced hyperpolarization in SMCs, but not in ECs, of the mesenteric artery. These results show that transfer of EC hyperpolarization or of a small molecule to SMCs through MEGJs is essential and sufficient to explain EDHF.     

Endothelial cell pathway for conduction of hyperpolarization and vasodilation along hamster feed artery

Acetylcholine (ACh) evokes the conduction of vasodilation along resistance microvessels. However, it is not known which cell layer (endothelium or smooth muscle) serves as the conduction pathway. In isolated, cannulated feed arteries ( approximately 70 microm in diameter at 75 mm Hg; length approximately 4 mm) of the hamster retractor muscle, we tested the hypothesis that endothelial cells provide the pathway for conduction. Microiontophoresis of ACh (500 ms, 500 nA) onto the distal end of a feed artery evoked hyperpolarization (-13+/-2 mV) of both cell layers with vasodilation (15+/-1 microm) along the entire vessel. To selectively damage endothelial cells (confirmed by loss of vasodilation to ACh and labeling of disrupted cells with propidium iodide), an air bubble was perfused through a portion of the vessel lumen, or a 70-kDa fluorescein-conjugated dextran (FCD) was illuminated within a segment (300 microm) of the lumen. After endothelial cell damage, hyperpolarization and vasodilation conducted up to, but not through, the treated segment. To selectively damage smooth muscle cells (confirmed by loss of vasoconstriction to phenylephrine and labeling with propidium iodide), FCD was perifused around the vessel and illuminated. Vasodilation and hyperpolarization conducted past the disrupted smooth muscle cells without attenuation. We conclude that endothelial cells provide the pathway for conducting hyperpolarization and vasodilation along feed arteries in response to ACh.     

Myoendothelial coupling is unidirectional in guinea pig spiral modiolar arteries

Gap junctions (GJs) facilitate communication and promote transfer of signaling molecules or current between adjacent cells in various organs to coordinate cellular activity. In arteries, homocellular GJs are present between adjacent smooth muscle cells (SMCs) and between adjacent endothelial cells (ECs), whilst many arteries also exhibit heterocellular GJs between SMCs and ECs. To test the hypothesis that there is differential cell coupling in guinea pig spiral modiolar arteries (SMA), we used intracellular recording technique to record cellular activities simultaneously in ECs or SMCs in acutely isolated guinea pig SMA preparations. Cell types were identified by injection of a fluorescent dye, propidium iodide (PI), through recording microelectrodes. Stable intracellular recordings were made in 120 cells among which 61 were identified as SMCs and 28 as ECs. Dual intracellular recordings were conducted to detect the coexistence of the two distinct levels of resting potential (RP) and to estimate the intensity of electrical coupling between two cells by a current pulse of up to 0.5-1.5 nA. The electrotonic potential was detected not only in the current-injected cell, but also in the majority of non-injected cells. The electrical coupling ratios (ECRs) of homocellular cells were not significant (P>0.05) (0.084±0.032 (n=6) and 0.069±0.031 (n=7) for EC-EC and SMC-SMC pairs, respectively). By contrast, the ECRs of heterocellular cells were significantly different when a current pulse (1.5 nA, 2s) was injected into EC and SMC respectively (0.072±0.025 for EC; 0.003±0.001 for SMC, n=5, P<0.01). The putative gap junction blocker 18β-glycyrrhetinic acid significantly attenuated electrical coupling in both homocellular and heterocellular forms. The results suggest that homocellular GJs within SMCs or ECs are well coordinated but myoendothelial couplings between ECs and SMCs are unidirectional.     

Electrophysiological basis of arteriolar vasomotion in vivo

We tested the hypothesis that cyclic changes in membrane potential (E(m)) underlie spontaneous vasomotion in cheek pouch arterioles of anesthetized hamsters. Diameter oscillations (approximately 3 min(-1)) were preceded (approximately 3 s) by oscillations in E(m) of smooth muscle cells (SMC) and endothelial cells (EC). Oscillations in E(m) were resolved into six phases: (1) a period (6 +/- 2 s) at the most negative E(m) observed during vasomotion (-46 +/- 2 mV) correlating (r = 0.87, p < 0.01) with time (8 +/- 2 s) at the largest diameter observed during vasomotion (41 +/- 2 microm); (2) a slow depolarization (1.8 +/- 0.2 mV s(-1)) with no diameter change; (3) a fast (9.1 +/- 0.8 mV s(-1)) depolarization (to -28 +/- 2 mV) and constriction; (4) a transient partial repolarization (3-4 mV); (5) a sustained (5 +/- 1 s) depolarization (-28 +/- 2 mV) correlating (r = 0.78, p < 0.01) with time (3 +/- 1 s) at the smallest diameter (27 +/- 2 microm) during vasomotion; (6) a slow repolarization (2.5 +/- 0.2 mV s(-1)) and relaxation. The absolute change in E(m) correlated (r = 0.60, p < 0.01) with the most negative E(m). Sodium nitroprusside or nifedipine caused sustained hyperpolarization and dilation, whereas tetraethylammonium or elevated PO(2) caused sustained depolarization and constriction. We suggest that vasomotion in vivo reflects spontaneous, cyclic changes in E(m) of SMC and EC corresponding with cation fluxes across plasma membranes.     

Myoendothelial coupling is not prominent in arterioles within the mouse cremaster microcirculation in vivo

A smooth muscle hyperpolarization is essential for endothelium-dependent hyperpolarizing factor-mediated dilations. It is debated whether the hyperpolarization is induced by a factor (endothelium-derived hyperpolarizing factor) and/or is attributable to direct current transfer from the endothelium via myoendothelial gap junctions. Here, we measured membrane potential in endothelial cells (EC) and smooth muscle cells (SMC) in vivo at rest and during acetylcholine (ACh) application in the cremaster microcirculation of mice using sharp microelectrodes before and after application of specific blockers of Ca2+-dependent K+ channels (K(Ca)). Moreover, diameter changes in response to ACh were studied. Membrane potential at rest was lower in EC than SMC (-46.6+/-1.0 versus -36.5+/-1.0mV, P<0.05). Bolus application of ACh induced robust hyperpolarizations in EC and SMC, but the amplitude (11.1+/-0.9 versus 5.1+/-0.9mV, P<0.05) and duration of the response (10.7+/-0.8 versus 7.5+/-1.0s, P<0.05) were larger in EC. Blockers of large conductance K(Ca) (charybdotoxin or iberiotoxin) abrogated ACh-induced hyperpolarizations in SMC but did not alter endothelial hyperpolarizations. In contrast, apamin, a blocker of small conductance K(Ca) abolished ACh-induced hyperpolarizations in EC and had only small effects on SMC. ACh-induced dilations were strongly attenuated by iberiotoxin but only slightly by apamin. We conclude that myoendothelial coupling in arterioles in vivo in the murine cremaster is weak, as EC and SMC behaved electrically different. Small conductance K(Ca) mediate endothelial hyperpolarization in response to ACh, whereas large conductance K(Ca) are important in SMC. Because tight myoendothelial coupling was found in vitro in previous studies, we suggest that it is differentially regulated between vascular beds and/or by mechanisms acting in vivo.     

Mechanisms of induction of endothelial cell E-selectin expression by smooth muscle cells and its inhibition by shear stress

E-selectin is a major adhesion molecule expressed by endothelial cells (ECs), which are exposed to shear stress and neighboring smooth muscle cells (SMCs). We investigated the mechanisms underlying the modulation of EC E-selectin expression by SMCs and shear stress. SMC coculture induced rapid and sustained increases in expression of E-selectin and phosphorylation of interleukin-1 (IL-1) receptor-associated kinase glycoprotein-130, as well as the downstream mitogen-activated protein kinases (MAPKs) and Akt. By using specific inhibitors, dominant-negative mutants, and small interfering RNA, we demonstrated that activations of c-Jun-NH(2)-terminal kinase (JNK) and p38 of the MAPK pathways are critical for the coculture-induced E-selectin expression. Gel shifting and chromatin immunoprecipitation assays showed that SMC coculture increased the nuclear factor-kappaB (NF-kappaB)-promoter binding activity in ECs; inhibition of NF-kappaB activation by p65-antisense, lactacystin, and N-acetyl-cysteine blocked the coculture-induced E-selectin promoter activity. Protein arrays and blocking assays using neutralizing antibodies demonstrated that IL-1beta and IL-6 produced by EC/SMC cocultures are major contributors to the coculture induction of EC signaling and E-selectin expression. Preshearing of ECs at 12 dynes/cm(2) inhibited the coculture-induced EC signaling and E-selectin expression. Our findings have elucidated the molecular mechanisms underlying the SMC induction of EC E-selectin expression and the shear stress protection against this SMC induction.     

Neutrophils, lymphocytes, and monocytes exhibit diverse behaviors in transendothelial and subendothelial migrations under coculture with smooth muscle cells in disturbed flow

Atherosclerosis develops at regions of the arterial tree exposed to disturbed flow. The early stage of atherogenesis involves the adhesion of leukocytes (white blood cells [WBCs]) to and their transmigration across endothelial cells (ECs), which are located in close proximity to smooth muscle cells (SMCs). We investigated the effects of EC/SMC coculture and disturbed flow on the adhesion and transmigration of 3 types of WBCs (neutrophils, peripheral blood lymphocytes [PBLs], and monocytes) using our vertical-step flow (VSF) chamber, in which ECs were cocultured with SMCs in collagen gels. Such coculture significantly increased the adhesion and transmigration of neutrophils, PBLs, and monocytes under VSF, particularly in the reattachment area, where the rolling velocity of WBCs and their transmigration time were decreased, as compared with the other areas. Neutrophils, PBLs, and monocytes showed different subendothelial migration patterns under VSF. Their movements were more random and shorter in distance in the reattachment area. Coculture of ECs and SMCs induced their expressions of adhesion molecules and chemokines, which contributed to the increased WBC adhesion and transmigration. Our findings provide insights into the mechanisms of WBC interaction with the vessel wall (composed of ECs and SMCs) under the complex flow environments found in regions of prevalence for atherogenesis.     

JTT-705 blocks cell proliferation and angiogenesis through p38 kinase/p27(kip1) and Ras/p21(waf1) pathways

The excessive proliferation and migration of vascular smooth muscle cells (SMCs) participate in the growth and instability of atherosclerotic plaque. We examined the direct role of a newly developed chemical inhibitor of cholesteryl ester transfer protein, JTT-705, on SMC proliferation and angiogenesis in endothelial cells (ECs). JTT-705 inhibited human coronary artery SMC proliferation. JTT-705 induced the phosphorylation of p38 mitogen-activated protein kinase (MAPK) and extracellular-signal-regulated kinases (ERK) in SMCs. In addition, the anti-proliferative effects of JTT-705 in SMCs were blocked by p38 MAPK inhibitor. JTT-705 induced the upregulation of p-p21(waf1), and this effect was blocked by dominant-negative Ras (N17), but not by inhibitors of p38 MAPK or ERK. In addition, JTT-705 also induced the upregulation of p27(kip1), and this effect was blocked by p38 MAPK inhibitor. Interestingly, culture medium from JTT-705-treated SMCs blocked human coronary artery EC tube formation in an in vitro model of angiogenesis indirectly via a decrease in vascular endothelial growth factor (VEGF) from SMCs and directly via an anti-proliferative effect in ECs. JTT-705 blocked the proliferation of SMCs through the activation of p38 kinase/p27(kip1) and Ras/p21(waf1) pathways, and simultaneously blocked EC tube formation associated with a decrease in VEGF production from SMCs and an anti-proliferative effect in ECs. Our results indicate that JTT-705 may induce a direct anti-atherogenic effect in addition to its inhibitory effect of CETP activity.     

Acetylcholine-induced relaxation and hyperpolarization in small bovine adrenal cortical arteries: role of cytochrome P450 metabolites

The present study characterizes the vascular responses of isolated small bovine adrenal cortical arteries to acetylcholine, an endogenous neurotransmitter in the adrenal gland. Acetylcholine (10(-10) to 10(-6) m) elicited a concentration-dependent relaxation, with a maximal relaxation of 96 +/- 1% and EC50 of 4.2 nm. The relaxation was abolished by endothelial removal and attenuated by the nitric oxide synthase inhibitor N-nitro-L-arginine (L-NA, 30 microm) but not by the cyclooxygenase inhibitor indomethacin (10 microm). The maximal relaxation and EC50 of acetylcholine in the presence of L-NA were 87 +/- 4% and 22 nm, respectively. The acetylcholine-induced, indomethacin- and L-NA-resistant relaxation was eliminated by high K+ and markedly inhibited by the cytochrome P450 inhibitors SKF 525A (10 microm) and miconazole (10 microm). The maximal relaxations and EC50s with SKF 525A and miconazole were 56 +/- 8 and 72 +/- 2% and 0.8 and 0.5 microm, respectively. In indomethacin- and L-NA-treated arteries, acetylcholine induced a smooth muscle hyperpolarization, which was blocked by SKF 525A (3 +/- 1 mV vs. 15 +/- 2 mV of control). Arachidonic acid (10(-9) to 10(-5) m) and 14,15-epoxyeicosatrienoic acid (14,15-EET, 10(-9) to 10(-5) m), a cytochrome P450 metabolite of arachidonic acid, also evoked relaxations in small adrenal arteries, with maximal relaxations of 56 +/- 4 and 90 +/- 5%, respectively. The arachidonic acid-induced relaxation was blocked by SKF 525A. Using high-pressure liquid chromatography and gas chromatography/mass spectrometry analysis, EETs were identified in small adrenal arteries. These results demonstrate that acetylcholine is a potent vasodilator of small adrenal cortical arteries. The acetylcholine-induced relaxation is largely mediated by an endothelium-dependent hyperpolarization mechanism, presumably through cytochrome P450 metabolites of arachidonic acid.     

Cyclic tensile strain triggers a sequence of autocrine and paracrine signaling to regulate angiogenic sprouting in human vascular cells

Mechanical signals regulate blood vessel development in vivo, and have been demonstrated to regulate signal transduction of endothelial cell (EC) and smooth muscle cell (SMC) phenotype in vitro. However, it is unclear how the complex process of angiogenesis, which involves multiple cell types and growth factors that act in a spatiotemporally regulated manner, is triggered by a mechanical input. Here, we describe a mechanism for modulating vascular cells during sequential stages of an in vitro model of early angiogenesis by applying cyclic tensile strain. Cyclic strain of human umbilical vein (HUV)ECs up-regulated the secretion of angiopoietin (Ang)-2 and PDGF-ββ, and enhanced endothelial migration and sprout formation, whereas effects were eliminated with shRNA knockdown of endogenous Ang-2. Applying strain to colonies of HUVEC, cocultured on the same micropatterned substrate with nonstrained human aortic (HA)SMCs, led to a directed migration of the HASMC toward migrating HUVECs, with diminished recruitment when PDGF receptors were neutralized. These results demonstrate that a singular mechanical cue (cyclic tensile strain) can trigger a cascade of autocrine and paracrine signaling events between ECs and SMCs critical to the angiogenic process.     

Perivascular Innervation: A Multiplicity of Roles in Vasomotor Control and Myoendothelial Signaling

The control of vascular resistance and tissue perfusion reflect coordinated changes in the diameter of feed arteries and the arteriolar networks they supply. Against a background of myogenic tone and metabolic demand, vasoactive signals originating from perivascular sympathetic and sensory nerves are integrated with endothelium‐derived signals to produce vasodilation or vasoconstriction. PVNs release adrenergic, cholinergic, peptidergic, purinergic, and nitrergic neurotransmitters that lead to SMC contraction or relaxation via their actions on SMCs, ECs, or other PVNs. ECs release autacoids that can have opposing actions on SMCs. Respective cell layers are connected directly to each other through GJs at discrete sites via MEJs projecting through holes in the IEL. Whereas studies of intercellular communication in the vascular wall have centered on endothelium‐derived signals that govern SMC relaxation, attention has increasingly focused on signaling from SMCs to ECs. Thus, via MEJs, neurotransmission from PVNs can evoke distinct responses from ECs subsequent to acting on SMCs. To integrate this emerging area of investigation in light of vasomotor control, the present review synthesizes current understanding of signaling events that originate within SMCs in response to perivascular neurotransmission in light of EC feedback. Although often ignored in studies of the resistance vasculature, PVNs are integral to blood flow control and can provide a physiological stimulus for myoendothelial communication. Greater understanding of these underlying signaling events and how they may be affected by aging and disease will provide new approaches for selective therapeutic interventions.     

Shear stress inhibits adhesion molecule expression in vascular endothelial cells induced by coculture with smooth muscle cells

Vascular endothelial cells (ECs), which exist in close proximity to vascular smooth muscle cells (SMCs), are constantly subjected to blood flow-induced shear stress. Although the effect of shear stress on endothelial biology has been extensively studied, the influence of SMCs on endothelial response to shear stress remains largely unexplored. We examined the potential role of SMCs in regulating the shear stress-induced gene expression in ECs, using a parallel-plate coculture flow system in which these 2 types of cells were separated by a porous membrane. In this coculture system, SMCs tended to orient perpendicularly to the flow direction, whereas the ECs were elongated and aligned with the flow direction. Under static conditions, coculture with SMCs induced EC gene expression of intercellular adhesion molecule-1 (ICAM-1), vascular adhesion molecule-1 (VCAM-1), and E-selectin, while attenuating EC gene expression of endothelial nitric oxide synthase (eNOS). Shear stress significantly inhibited SMC-induced adhesion molecule gene expression. These EC responses under static and shear conditions were not observed in the absence of close communication between ECs and SMCs, and they were also not observed when ECs were cocultured with fibroblasts instead of SMCs. Our findings indicate that under static conditions, coculture with SMCs induces ICAM-1, VCAM-1, and E-selectin gene expression in ECs. These coculture effects are inhibited by shear stress and require specific interaction between ECs and SMCs in close contact.     

Expression of thrombomodulin by smooth muscle cells in culture: different effects of tumor necrosis factor and cyclic adenosine monophosphate on thrombomodulin expression by endothelial cells and smooth muscle cells in culture.

Thrombomodulin (TM), a critical component of the protein C anticoagulant pathway, has previously been localized to endothelial cells (EC), but not smooth muscle cells (SMC) of the blood vessel wall. We demonstrate that cultured rat, bovine, as well as human SMC, but not blood vessel wall smooth muscle tissue, possess significant functional levels of TM and TM mRNA. Cyclic adenosine monophosphate stimulates TM expression in cultured SMC, but not EC, while tumor necrosis factor suppresses TM expression in EC but not cultured SMC. We postulate that following acute or chronic EC injury, luminal SMC can express TM, and are therefore able to protect the damaged blood vessel from thrombosis.     

Direct and indirect effects of pulsatile shear stress on the smooth muscle cell.

BACKGROUND: Anastomotic intimal hyperplasia is still an unsolved problem after small caliber prosthetic bypass grafting. Oscillatory turbulent flow occurs at the end to side anastomosis, and produces various effects on smooth muscle cells (SMCs) and endothelial cells (ECs), which compose intimal hyperplasia. We examined the influences of pulsatile oscillating shear stress on smooth muscle cells mitogenic activity induced by sheared endothelial cells. METHODS:1) Smooth muscle cells were cultured under three different pulsatile shear conditions (mean: 0, 6, and 60 dyne/cm2). 2) Endothelial cells were cultured under both static and sheared condition (mean: 60 dyne/cm2). Using the conditioned media from each well, SMCs were cultured under static and sheared conditions (60 dyne/cm2). Four groups of SMCs were devised by combining the two types of media and the two culture conditions. SMC colony spreading distances were measured as an index of combined migration and proliferation activity. An MTT assay and a cell counting assay were used to determine the proliferation activities of SMCs. RESULTS: 1) SMC spreading activity was suppressed by shear stress. SMC proliferative activity was stimulated by pulsatile turbulent shear stress. 2) SMC spreading activity was stimulated by mitogens derived from ECs under shear stress. However, this augmented SMC spreading activity was attenuated under sheared conditions. The mitogens derived from ECs under pulsatile shear stress had no effects on SMC proliferation activity. CONCLUSIONS: Pulsatile oscillating shear stress attenuates SMC migration activity induced by EC-denve mitogens and stimulates SMC proliferative activity.     

Stem cell origins of intimal cells in graft arterial disease

Long-term solid organ allografts develop diffuse arterial intimal lesions (graft arterial disease [GAD]), consisting of smooth muscle cells (SMCs), extracellular matrix, and admixed mononuclear leukocytes. Although the exact mechanisms are unknown, alloresponses likely induce inflammatory cells and/or dysfunctional vascular wall cells to secrete growth factors that promote SMC intimal recruitment, proliferation, and matrix synthesis. GAD eventually culminates in vascular stenosis and ischemic graft failure. Although prior work demonstrated that the endothelium and medial SMCs and the vast majority of endothelial cells (ECs) lining GAD lesions in cardiac allografts are derived from donors, the intimal SMC origin could not be determined. Recent reports suggest that intimal lesions in allograft vessels may also contain host-derived ECs and SMCs. In light of these findings, it is noteworthy that subpopulations of bone marrow and circulating cells have also been shown to differentiate into ECs and SMCs. Here we review recent developments in the understanding of vascular wall cell recruitment that are forcing a re-evaluation of the pathogenic mechanisms underlying GAD, as well as those occurring in more “conventional” atherosclerosis. The demonstration of the host origin of intimal SMCs in GAD lays the groundwork for future interventions where therapeutic genes or drugs may be targeted not to donor medial SMCs, but rather to recipient SM precursor cells.     

Overexpression of endothelial NO synthase induces angiogenesis in a co-culture model

OBJECTIVE: Angiogenesis is a complex multistep process that involves endothelial cell (EC) migration, proliferation and differentiation into vascular tubes. NO has been reported to be a downstream mediator in the angiogenic response to a variety of growth factors, but the mechanisms by which NO promotes neovessel formation is not clear. We hypothesized that NO directly contributes to EC migration and capillary tube formation. METHODS: Since previous studies have noted important biological differences between NO produced pharmacologically by NO-donor compounds compared to that from NO synthase (NOS), we used a cell-based gene transfer approach to increase NO production in a co-culture model of in vitro angiogenesis. Rat smooth muscle cells (SMCs) were transfected with plasmids containing VEGF(121), VEGF(165) (SMC(VEGF)), endothelial NOS (SMC(eNOS)) or the empty vector (SMC(Cont)). Expression of the eNOS in SMC(eNOS) was confirmed by Northern analysis, NADPH-diaphorase activity, and nitrite/nitrate levels, whereas VEGF production was confirmed using ELISA. Calf pulmonary artery ECs (CPAECs) were cultured on the fibrin matrix with (co-culture) or without underlying SMCs (monoculture). RESULTS: Co-culture of ECs with SMC(Cont) had no effect on EC differentiation compared with EC in monoculture (differentiation index, DI=2.8+/-3.4 vs. 2.1+/-2.8, respectively, NS). In contrast, co-culture with SMC(eNOS) resulted in the formation of extensive capillary-like structures within 48 h (DI=17.2+/-5.9, P<0.001 versus SMC(Cont)), which was significantly inhibited using a NOS inhibitor, L-NAME (3 mM) (DI=4.5+/-3.04, P<0.001 versus SMC(eNOS)). Similarly, SMC(VEGF121) induced an angiogenic response (DI=14.2+/-3.8), which was also significantly inhibited by L-NAME (DI=5.9+/-1.8, P<0.05). In using the Boyden chamber model, SMC(eNOS), but not SMC(Cont) increased EC migration to a similar extent as SMC(VEGF121), and both were significantly inhibited with L-NAME. CONCLUSIONS: These data support an important paracrine role for endogenously produced NO in EC migration and differentiation in vitro, and suggest that the cell-based eNOS gene transfer may be a useful approach to increase new blood vessel formation in vivo.     

Induction of IG9 monocyte adhesion molecule expression in smooth muscle and endothelial cells after balloon arterial injury in cholesterol-fed rabbits

The expression of monocyte-specific adhesion molecules and chemokines by cell types within the vessel wall plays an important role in foam cell accumulation during atherosclerotic plaque development. We previously identified IG9, a novel monocyte adhesion protein that is expressed on endothelial cells (ECs) overlying human and rabbit advanced atherosclerotic plaques. The present study was designed to determine the temporal and spatial expression of IG9 and the chemokine, monocyte chemoattractant protein-1 (MCP-1), after balloon injury with (double injury) or without (single injury) prior air desiccation EC injury in the femoral arteries of rabbits fed a high-cholesterol diet. By immunohistochemical analyses, intense reactivity with monoclonal antibodies to IG9 and MCP-1 was detected 24 hours after single injury in medial smooth muscle cells (SMCs) and in SMCs of adventitial microvessels. However, monocyte infiltration of the tunica media was minimal or not detected in these sections. IG9 and MCP-1 antibody reactivity in vessel sections 28 days after single injury and 24 hours, 7 days, and 28 days after double injury was localized to medial and neointimal SMCs, foam cells, and luminal ECs overlying the plaques. Uninjured rabbit (cholesterol or normal diet) vessel sections exhibited minimal IG9 and MCP-1 immunostaining. In vitro studies using human aortic SMCs demonstrated IG9 protein induction after 24 hours of treatment with platelet-derived growth factor-BB and interferon-gamma or epidermal growth factor. IG9 expression was further increased by pretreatment of SMCs with the proatherogenic lipid, minimally oxidized low density lipoprotein. After balloon injury (24 hours), IG9 is induced in vascular SMCs before the detectable accumulation of monocytes within the vessel wall. Thus, the expression of IG9 by SMCs as well as by ECs may be an important factor in the accumulation of foam cells in atherosclerotic plaque development after arterial injury.     

Endothelial cells lining transjugular intrahepatic portasystemic shunts originate in hepatic sinusoids: implications for pseudointimal hyperplasia

The phenotype of the endothelial cells (ECs) in the pseudointima of transjugular intrahepatic portasystemic shunts (TIPS) and the mechanisms of pseudointima formation after TIPS were unknown. We hypothesized that TIPS were lined by hepatic sinusoidal ECs, which stimulated the migration of smooth muscle cells (SMCs) into the pseudointima and their proliferation. Studies were done with the following specific aims: (1) isolation of ECs from TIPS pseudointima and comparison of their phenotype with human cirrhotic sinusoidal and vascular ECs derived from hepatic and portal veins as well as aorta, and (2) testing of the effects of TIPS ECs on TIPS-derived SMC migration and proliferation. ECs were isolated from eight TIPS retrieved from liver explants by immunomagnetic separation using monodispersed magnetizable polystyrene beads (Dynabeads M-450) coated with Ulex Europeus 1. EC phenotypes were examined by transmission electron microscopy, factor VIII-related antigen, CD31, CD14, and CD34 expression, uptake of acetylated LDL and secretion of type IV collagen. The effects of EC-conditioned media on SMC migration and proliferation were tested in multiwell chemotaxis chambers and by cell counting, respectively. ECs were obtained from TIPS pseudointima with >95% purity. The phenotype of TIPS-derived ECs matched that of cirrhotic sinusoidal endothelium (both expressed CD14) and differed from that of vascular endothelium (CD14 negative, Weibel-Palade positive). Conditioned media from both stenosed (n = 3) and nonstenosed (n = 3) TIPS-derived endothelial cells produced a marked (>100%) P <.001 increase in migration as well as (up to 88%) P <.01 proliferation of SMCs from both stenosed (n = 3) as well as nonstenosed TIPS (n = 3). These data indicate that TIPS pseudointima are lined by hepatic sinusoidal endothelial cells, which stimulate pseudointima formation by increasing SMC migration and proliferation.     

Production of platelet-derived growth factor-like molecules by cultured arterial smooth muscle cells accompanies proliferation after arterial injury.

The migration and proliferation of smooth muscle cells (SMCs) within the intima of arteries following mechanical injury is thought to be initiated by vessel wall injury and release of growth factors, in particular the platelet-derived growth factor (PDGF). However, the mechanism by which SMC proliferation is regulated after platelet interaction with the vessel wall has ceased is unknown. Here we show that SMCs derived from the intima of injured rat arteries (intimal SMCs) are phenotypically distinct from SMCs from unmanipulated vessels (medial SMCs). Intimal SMCs secrete 5-fold greater amounts of PDGF-like activity into conditioned medium in culture, have fewer receptors for 125I-labeled PDGF, and are not mitogenically stimulated by exogenous purified PDGF. This study demonstrates that two SMC phenotypes can develop in the adult rat artery and suggests that SMC proliferation in vivo may be controlled, in part, by SMCs that produce PDGF-like molecules.