Organ culture of rat carotid artery: maintenance of morphological characteristics and of pattern of matrix synthesis

ROCK inhibition prevents fetal serum-induced alteration in structure and function of organ-cultured mesenteric artery

Chronic treatment with fetal bovine serum (FBS) causes contractility reduction, morphological alteration and DNA synthesis in organ-cultured vascular tissues. Here, we tested the hypothesis that chronic inhibition of ROCK has a protective effect on FBS-induced alterations in small arteries. Rabbit mesenteric arterial rings were cultured in FBS-supplemented culture medium with or without Y-27632, a reversible ROCK inhibitor. Chronic Y-27632 treatment prevented FBS-induced gradual arterial constriction, wall thickening, reduced contractility, and increased ROCK-specific MYPT1 Thr853 phosphorylation. Treatment with Y-27632 also prevented decreased eNOS mRNA expression, and reduced acetylcholine-induced relaxation. Sudden application of Y-27632 to pre-cultured rings reduced MYPT1 phosphorylation and re-widened the constricted rings. Chronic treatment with Y-27632, however, rather augmented than reduced the FBS-induced RhoA over-expression, also increased ROCK1 and MYPT1 expression and averted the FBS-induced reduction of MLC expression, suggesting a compensation of inhibited RhoA/ROCK activity. Sudden removal of Y-27632 caused a rebound in MYPT1 phosphorylation and vasoconstriction in rabbit mesenteric artery. To test which ROCK isoform has greater involvement in FBS-induced contraction, haploinsufficient Rock1+/- and Rock2+/- mouse mesenteric arterial rings were subjected to organ-culture. FBS-induced contraction and RhoA over-expression in either heterozygous animal was not different from wild-type animals. These results suggest that FBS-induced contraction is mediated by up-regulation of RhoA and subsequent activation of ROCK. In conclusion, chronic ROCK inhibition produces some effects that protect against FBS-stimulated vasoconstriction and remodeling. There are also negative effects that a sudden withdrawal of ROCK inhibitor might cause a stronger vasoconstriction than before it was used.

Biomimetic bone mechanotransduction modeling in neonatal rat femur organ cultures: structural verification of proof of concept

The goal of this work was to develop and validate a whole bone organ culture model to be utilized in biomimetic mechanotransduction research. Femurs harvested from 2-day-old neonatal rat pups were maintained in culture for 1 week post-harvest and assessed for growth and viability. For stimulation studies, femurs were physiologically stimulated for 350 cycles 24 h post-harvest then maintained in culture for 1 week at which time structural tests were conducted. Comparing 1 and 8 days in culture, bones grew significantly in size over the 7-day culture period. In addition, histology supported adequate diffusion and organ viability at 2 weeks in culture. For stimulation studies, 350 cycles of physiologic loading 24 h post-harvest resulted in increased bone strength over the 7-day culture period. In this work, structural proof of concept was established for the use of whole bone organ cultures as mechanotransduction models. Specifically, this work established that these cultures grow and remain viable in culture, are adequately nourished via diffusion and are capable of responding to a brief bout of mechanical stimulation with an increase in strength.

The elastic lamellae of devitalized arteries calcify when incubated in serum: evidence for a serum calcification factor

OBJECTIVE

To determine whether serum contains an activity that induces artery calcification.

METHODS AND RESULTS

The elastic lamellae of devitalized rat aortas calcify rapidly in rat or bovine serum, or in human serum provided [Pi] > or =2 mmol/L. This calcification is attributable to a potent serum calcification factor (SCF), one that causes devitalized aortas to calcify when incubated in DMEM containing as little as 1.5% serum but not in DMEM alone. The SCF that initiates medial elastin calcification has the same 50- to 150-kDa size and protease sensitivity as the SCF shown previously to initiate calcification of type I collagen. Our working hypothesis is that the same SCF initiates calcification of collagen and elastin, and that this SCF arises from sites of normal bone mineralization and, like alkaline phosphatase, is released into general circulation. The SCF does not initiate medial elastin calcification in living arteries, which suggests that vascular cells may prevent this calcification. This hypothesis is supported by the observations that living arteries secrete the calcification inhibitor matrix Gla protein (MGP); that inactivation of MGP with warfarin causes living arteries to calcify; and that addition of MGP to medium containing warfarin prevents this calcification.

CONCLUSIONS

The elastic lamellae of devitalized aortas calcify rapidly in serum.

Long-term effects of intracellular calcium and growth factors on excitation and contraction in smooth muscle

Modulation of vascular smooth muscle cells from a contractile to a synthetic phenotype is thought to be important in the development of the atherosclerotic lesion. Such modulation depends on growth factors and is influenced by cell-cell and cell-matrix interactions. Whereas smooth muscle cells in the vessel wall are contractile, dispersed cells in culture rapidly modulate to synthetic phenotype, which complicates long-term in vitro studies. In contrast, vascular segments or smooth muscle strips in organ culture can maintain contractility for at least a week, sufficient for studies involving altered metabolism or protein expression. Examples are effects of endogenous polyamines on membrane ion channels and excitation-contraction coupling. While smooth muscle tissue is well preserved in serum-free culture, growth stimulation with fetal calf serum (FCS) causes multiple effects, including decreased contractility, ultrastructural changes, decreased expression of L-type Ca2+ channels, and increased SR release of Ca2+ via ryanodine receptors. These are all consequences of increased basal [Ca2+]i caused by FCS, as they are reversed by culture with verapamil in a concentration (1 microM) that does not inhibit stimulation of DNA and protein synthesis by FCS. The effects of FCS on contractility and Ca2+ channel expression are mimicked in serum-free culture with increased [Ca2+]i. Contractile protein patterns, including myosin isoform composition, are unaffected by FCS, suggesting that reversal to synthetic phenotype is limited and not the immediate cause of decreased contractility.

Enhanced neointimal growth in cultured rabbit aorta following in vivo balloon angioplasty

We have used in vivo balloon catheterization in combination with in vitro organ culture to develop a model system for vascular neointima formation. A Fogarty balloon catheter was used to deendothelialize and rupture the internal elastic lamina of aortae in adult rabbits. After three d of recovery, aortae were harvested, divided into segments, and placed into organ culture. We obtained a daily index of cell proliferation in cultured vessels using [3H]thymidine incorporation into DNA. Also, segments were collected and processed for routine histology or immunohistochemistry. Aortic segments that had undergone ballooning 3 d before harvest and then cultured exhibited diffuse neointimal growth after several d in vitro, whereas those from sham-operated (nonballooned) rabbits showed generally only a single endothelial cell layer that is characteristic of normal intima. Aortae that were harvested, balloon-damaged in vitro, and then cultured exhibited no neointimal growth. The neointima that developed in cultured segments from in vivo ballooned rabbits was primarily of smooth muscle cell origin as determined by positive immunostaining for alpha-smooth muscle actin. The intima:media thickness ratios were significantly higher in aortic segments from ballooned rabbits at harvest and after 4 or 7 d in culture compared with those from nonballooned rabbits. Also, the [3H]thymidine index was higher in the in vivo ballooned aorta compared to non-ballooned or in vitro ballooned vessel. We conclude that ballooning in vivo followed by exposure to blood-borne elements produces an enhanced proliferative response in cultured vessels that is distinct from other in vitro models of neointimal growth.

Carbenoxolone damages endothelium and enhances vasoconstrictor action in aortic rings

Carbenoxolone causes hypertension indirectly by inhibition of 11beta-hydroxysteroid dehydrogenase and consequent elevation of intracellular glucocorticoid levels and enhancement of vasoconstrictor action. We performed the present study to determine whether carbenoxolone also enhances vascular tone directly by mechanisms independent of glucocorticoids and other systemic influences. Exposure of rat aortic rings to 10 to 100 micromol/L carbenoxolone in aerated Krebs-Henseleit buffer for 24 hours resulted in concentration-dependent increases in angiotensin II (Ang II) (100 nmol/L)-stimulated contractions and significant shifting of the phenylephrine cumulative contraction curve to the left but not increases in KCI (120 mmol/L)-stimulated contractions. Maximal enhancement of Ang II contraction was 39 percent. In contrast, brief (15-minute) exposure to 100 micromol/L carbenoxolone did not alter Ang II contractions. Mechanical denudation of the endothelium obviated enhancement of Ang II contractions by carbenoxolone, suggesting interaction of carbenoxolone with the endothelium. Endothelium-dependent relaxation of precontracted rings to acetylcholine or ATP was reduced by more than 90 percent by 24-hour pretreatment with 100 micromol/L carbenoxolone but not with 100 micromol/L deoxycorticosterone acetate (a mineralocorticoid) or 100 mu mol/L glycyrrhizic acid (a natural 11beta-hydroxysteroid dehydrogenase inhibitor). Vascular smooth muscle relaxation with sodium nitroprusside was not inhibited by carbenoxolone. Incubation of cultured endothelial cells with 100 mu mol/L carbenoxolone for 24 hours did not inhibit nitric oxide synthase activity, as measured by conversion of [3H]L-arginine to [3H]L-citrulline. Electron micrography demonstrated that endothelial cell ultrastructure but not vascular smooth muscle cell ultrastructure was abnormal after incubation of rings for 24 hours with 100 micromol/L carbenoxolone. These studies suggest that carbenoxolone concentrations higher than 10 micromol/L enhance vasoconstrictor action via selective toxicity to the endothelium and elimination of endothelium-dependent relaxation.

Corticosterone metabolism and effects on angiotensin II receptors in vascular smooth muscle

It has been postulated that mineralocorticoids can bind to corticosteroid receptors in the kidney, because glucocorticoids are metabolized to inactive compounds. The present study was performed to delineate glucocorticoid metabolism by rat vascular tissue and to determine the activity of these metabolites. Vascular segments converted 25% to 30% of corticosterone (compound B), the major glucocorticoid in the rat, to 11-dehydrocorticosterone (compound A) but not to aldosterone or 6 beta-hydroxycorticosterone. In cultured vascular smooth muscle cells, 10% of compound B was converted to compound A, whereas > 60% of compound A was converted to compound B. The 11 beta-hydroxysteroid dehydrogenase inhibitor carbenoxolone (1 mumol/L) completely blocked conversion in both directions. Whereas 6 beta-hydroxycorticosterone did not upregulate angiotensin II receptor binding (a marker for corticosteroid action in vascular smooth muscle), compound A caused concentration-dependent upregulation. Compound A was almost (75%) as effective and as potent as compound B in upregulating angiotensin II binding. Upregulation elicited by exposure to compound A persisted in the presence of 1 mumol/L carbenoxolone, which completely prevented the conversion of compound A to compound B. Compound A, even in the presence of carbenoxolone, effected other glucocorticoid actions by inhibiting cell growth and potentiating angiotensin II-stimulated inositol phosphate formation. In summary, compound B and compound A are interconverted in vascular tissue, and the latter displays significant glucocorticoid action. The concentration excess of compound B in the circulation and the activity of its metabolite compound A will make it difficult for mineralocorticoids to gain access to corticosteroid receptors in the vasculature.

Viability studies of human valves prepared for use as allografts

The preimplantation viability status of pulmonary and aortic valves prepared for use as allografts by the methods in current use at Green Lane Hospital, Auckland was determined by autoradiography and culture. The valves were obtained from cadaver donors, disinfected in antibiotic solution and stored by cryopreservation. A group of 45 banked valves considered unsuitable for clinical use was assayed initially and very few were found to have viable fibroblasts in their leaflets. A series of 29 valves collected at postmortem examination then was assayed sequentially after each phase of the preparation procedure. Valves obtained within 24 hours of donor death usually retained considerable viability. However, in all but a minority of cases this declined markedly after antibiotic treatment and further still after cryopreservation, so that most valves were nonviable when thawed.

Percutaneous arterial gene transfer in a rabbit model. Efficiency in normal and balloon-dilated atherosclerotic arteries

The possibility of using an exclusively percutaneous strategy to deliver foreign DNA to normal and balloon-dilated atherosclerotic arteries was studied by analysis of transfection efficiency in a rabbit model. A total of 22 external iliac arteries from 22 rabbits (10 normal and 12 atherosclerotic) were transfected with a solution of luciferase expression vector plasmid and liposome, using a dual balloon-catheter system. Analysis of the transfected segments revealed luciferase activity in 10 of the 22 arteries (4/10 normal vs 6/12 balloon-injured atherosclerotic, P = NS); no activity could be detected in the contralateral limb arterial segments used as controls. Luciferase activity levels in successfully transfected segments measured 4.10 +/- 1.19 (m +/- SEM) Turner light units (TLU), with 3.03 +/- 1.16 TLU found in normals vs 4.81 +/- 1.87 TLU in balloon-injured atherosclerotic arteries (P = NS). In situ hybridization of successfully transfected atherosclerotic sections showed expression of the luciferase gene mRNA from rare cells (less than 1/1,000) limited to the neointimal lesion. Thus, expression of new genetic material may be achieved in both normal and balloon-dilated atherosclerotic arteries following an exclusively percutaneous approach. The low efficiency of the current delivery strategy, however, represents a potential limitation that must be improved if this strategy is to be applied as a therapeutic approach to human vascular disease.

Glycosaminoglycan synthesis by smooth muscle cells of differing phenotype and their response to endothelial cell conditioned medium

The synthesis of glycosaminoglycans (GAG) by contractile and irreversible synthetic phenotypes of vascular smooth muscle cells (SMC), and their response to endothelial cell conditioned medium (ECCM), has been investigated. Contractile SMC, (with a high volume fraction of myofilaments) were obtained by culturing freshly isolated rabbit aortic SMC for 3 days in primary culture. Irreversible synthetic SMC (with a low volume fraction of myofilaments) were obtained by serially passaging SMC to achieve more than 5 cumulative population doublings. In fresh medium both phenotypes produced significant amounts of GAG, but irreversible synthetic cells were more than twice as active on a per cell and cell volume basis. The proportions of individual GAG also changed with change in phenotype. Hyaluronic acid (HA) was the predominant GAG (78%) synthesised by contractile SMC but was significantly reduced (47%) in the irreversible synthetic cells with a corresponding increase in sulphated GAG (SGAG). The changed levels in GAG synthesis were independent of SMC growth. Both phenotypes responded to ECCM from bovine endothelial cells (EC) and significantly increased their synthesis of GAG and by the same relative amounts (50-100%). This response was density dependent, with ECCM from low and high density cultures of EC producing maximal responses and EC of intermediate densities producing minimal increases. Furthermore, dense cultures of EC preferentially stimulated SGAG. These findings show that an increase in synthesis of SMC GAG, and especially sulphated GAG as is found in atherosclerosis, may occur either through a change in phenotype or through endothelial mediated stimulation of GAG synthesis by either phenotype.

Acute and long-term effects of tissue culture on contractile reactivity in renal arteries of the rat

To evaluate long-term effects of contractile and mitogenic stimuli on the contractile reactivity of arterial smooth muscle, we measured the incorporation of the thymidine analogue 5-bromo-2'-deoxyuridine (BrdUrd) and mechanical responses in arterial segments that had been maintained in tissue culture. The experiments were performed on renal arteries that had been isolated from adult rats, chemically sympathectomized, mechanically denuded from endothelium and mounted under distension. Exposure of arterial segments for up to 3 weeks to culture medium supplemented with fetal calf serum resulted in the following consecutive changes: a strong acute contraction, selective pharmacological changes that included decreased contractile responses to phenylephrine and vasopressin and increased relaxing responses to isoproterenol, increased incorporation of BrdUrd, a progressive fall in contractile responses to all vasoconstrictor stimuli, and an increase in excitability. Serum-free medium resulted in a much smaller acute arterial contraction, induced less incorporation of BrdUrd, accelerated the occurrence of hyperexcitability, but did not affect early pharmacological changes or the subsequent fall in overall arterial contractility with tissue culture. Dialysis of the serum or addition of ketanserin abolished the contractile effect of serum but did not affect the incorporation of BrdUrd or the loss of contractility with tissue culture. Addition of serotonin to serum-free culture medium mimicked the contractile response to serum but not the stimulation of BrdUrd incorporation. These data indicate that tissue culture alters the properties of the arterial wall, that contraction does not underlie the proliferative response of arterial smooth muscle to serum-derived mitogens in vitro, and that stimulation of DNA synthesis does in itself not lead to selective changes in arterial contractility.

In vitro repair of the wounded porcine mitral valve

An organ culture of the anterior leaflet of the porcine mitral valve was developed and characterized in order to study the early events in the repair of small endocardial wounds. A linear superficial denuding endocardial injury was made with a nylon filament attached to a stereo tonearm. The repair process was studied by scanning and transmission electron microscopy over a 6-day period. By day 2 in culture, flattened endocardial cells at the wound edge extended processes out onto the wound edge. By 4 and 6 days, the wound was bridged over by spindle-shaped cells although gaps still remained between cells. In some areas, multilayering of cells beneath the surface was present. The results indicate that the initial events in in vitro endocardial repair involve both surface endocardial cells and interstitial cells.

Studies on aorta during development. I. Fetal rabbit aorta under ex vivo and in vitro conditions: rapid changes in smooth muscle cell phenotype, cell proliferation and cholesterol content with organ culture

The structural development of the already well defined fetal rabbit aortic wall from 22 to 31 days of gestation in vivo consists of increasing aortic wall thickness, elastic lamina continuities, extracellular matrix deposition, and maturing of the fine structure of the medial smooth muscle cells. In vivo at term (31 days), the mature aortic smooth muscle cells demonstrated the characteristic thin, thick and intermediate filaments, dense plaques, endoplasmic reticulum, golgi, plasmalemma vesicles and an incomplete basal lamina. The fetal aorta rapidly responded to organ culture with various changes. Fetal smooth muscle cells modified their phenotype to the synthetic state when cultured in both serum-supplemented and serum-free media. This smooth muscle cell modification occurred after 3 days of culture in fetal explants. The synthetic type smooth muscle cells (fetal) began to proliferate after 6 days of culture. This proliferation resulted in a peripheral outgrowth after 9 days of 10-20 layers in fetal cultures from serum-supplemented media and of 2-4 layers in serum-free media. The orderly arrangement of the internal elastic lamina and alternating medial layers of smooth muscle cells and elastic lamina seen in vivo was disrupted along with increased matrix after 9 days of fetal explant culture. Significant numbers of 'modified' synthetic phenotype smooth muscle cells were not observed in adult aortic explants until after 15 days in culture in serum supplemented media. The mature contractile phenotype smooth muscle cell predominated in adult explants cultured in serum-free media. Significant synthetic phenotype smooth muscle cell proliferation only occurred in adult explants after 15 days culture in serum-supplemented media. When compared to aorta in vivo evidence for increases in cholesterol esterification were observed in both fetal (9 days) and adult (15 days) explants cultured in both serum-supplemented and serum-free media. The fetal aorta in organ culture appeared to be more susceptible than the adult aorta to (a) phenotypic modulation of smooth muscle cells to the synthetic state, (b) smooth muscle cell proliferation, and (c) early cholesteryl ester accumulation.

Changes in collagen fibril diameters across artery walls including a correlation with glycosaminoglycan content

Collagen fibril diameters were measured at regular intervals across the walls of numerous arteries from human, pig and rat. In all vessels the smallest fibrils (mean-fibril diameters of 30-40 nm) occurred in the intima and inner media and the largest fibrils (MFDs 50-100 nm) in the outer adventitia. Between these two regions fibrils progressively increased in size. Circumferential and axial fibrils were of similar size and showed similar patterns of increase. At each sample site there was a range of diameters and frequency distributions were often multimodal with peaks 8 nm, or multiples of 8 nm, apart. Amounts of total and individual glycosaminoglycans (GAG) were determined at regular intervals across the wall of pig aorta and total and sulphated GAG levels were also determined at intervals across rat carotid artery using autoradiographic detection of incorporated [3H] glucosamine and 35S. In both vessels there was a strong correlation between decreasing GAG and increasing MFDs and over a narrow MFD range of 40 to 60 nm. These results demonstrate that collagen fibril diameters are excellent indicators to GAG levels and may be useful for making predictions about GAG levels in areas too small to sample biochemically.

Porcine aortic organ culture: a model to study the cellular response to vascular injury

Organ cultures of porcine thoracic aorta were studied to define the characteristics of this system as a model to study the reaction of endothelial cells (ECs) and the underlying smooth muscle cells (SMCs) to injury. Both nonwounded and wounded cultures, the latter having had part of the endothelial surface gently denuded with a scalpel blade, were studied over a 7 d period by scanning and transmission electron microscopy. The results showed that the nonwounded ECs underwent a shape change from elongated to polygonal within 24 h in culture. In both nonwounded and wounded explants there was cell proliferation beneath the nondenuded endothelium so that by 7 d several layers of cells were present showing features of the secretory type of SMCs. This proliferation, however, did not occur if the endothelium was totally removed from the aorta. There was also evidence of gaps between the surface ECs, and by 7 d lamellipodia of cells beneath the surface were present in these gaps. Occasionally, elongated cells were seen to be present on the surface of the endothelium. In the wounded organ culture, cell migration and proliferation occurred extending from the wound edge and producing a covering of cells on the denuded area. There were also multilayered cells beneath the surface similar to the nonwounded area. Occasional foam cells were seen in the depth of the multilayered proliferating cells. The results indicate that organ culture of porcine thoracic aorta is a good model to study the reaction of ECs and underlying SMCs to injury.