Organ cultures of rat aorta: a scanning and transmission electron microscopic study

Adaptation of mitochondrial expression and ATP production in dedifferentiating vascular smooth muscle cells

Atherosclerosis is one of the leading causes of morbidity and mortality in the Western world. Although the clinical manifestations of this disease are well documented, the etiology and progression remain to be fully understood. Recently, the mitochondria have been implicated in important cellular processes involved in development of atherosclerosis. Despite the link between mitochondria and atherosclerosis, early-phase mechanisms of the disease have yet to be elucidated. The aim of this project was to explore the role of mitochondria in vascular smooth muscle (VSMC) dedifferentiation. A murine in vitro model, involving organ culture of aortic tissue in serum-free media, was used. Mitochondrial function was measured by high-resolution respirometry. Proteins associated with the VSMC phenotype switch, as well as mitochondrial density, were assessed by immunoblotting. The findings show that intrinsic mitochondrial Complex I activity is significantly upregulated during VSMC dedifferentiation. Diminished coupling between phosphorylation and oxidation was also found, indicating a greater ADP:ATP ratio. This data suggests increased leak in the electron transport chain and altered mitochondrial function specifically at Complex I. This project provides important information regarding the role of mitochondria in the early atherosclerotic process and that detectable changes in mitochondrial function and expression are related to VSMC dedifferentiation.

The emerging issue of human resident arterial progenitors: the contribution of organ culture

Human femoral arteries were cultured up to 56 days. Samples were processed for light, immunohistochemical, and transmission electron microscopy. Arteries became rapidly depopulated; at day 42, an endothelial lining (CD31(+), Weibel-Palade bodies) developed on the intima; endothelium was in continuity with mesenchymal stromal cells (CD44(+), CD90(low), CD105(low)) placed on adventitia. The media-adventitia area showed heterogeneous cell populations. In long-term organ culture, femoral artery develops a continuous cell coverage that differentiates to endothelium on the intima exclusively. This suggests that distinct topographical factors, such as resident progenitors and/or matrix signals, are able to regulate vascular homeostasis in adult life.

Nitric oxide inhibition increases aortic wall matrix metalloproteinase-9 expression

OBJECTIVE

Nitric oxide (NO) may mediate vessel wall remodeling by regulating expression of matrix metalloproteinases (MMPs) and tissue inhibitors of metalloproteinases (TIMPs). This study tested the hypothesis that nitric oxide synthase (NOS) inhibition in whole aortic wall causes increases in cytokine-stimulated MMP and TIMP expression.

METHODS

Cultured infrarenal aortic segments from Sprague-Dawley rats were exposed to increasing concentrations (0, 0.1, 0.5, 1, and 5 mM; n = 6 per concentration) of N(G)-monomethyl-l-arginine (L-NMMA), a known inhibitor of NOS. This was in the presence of 2 ng/ml of interleukin-1beta, a known inducer of NOS, MMP, and TIMP expression. Media nitrate and nitrite (NO(x)) were measured at 72 h using the Saville method. Media MMP activity was measured using gelatin zymography. MMP-2 and -9 protein and mRNA levels were determined by Western blot and reverse transcriptase-polymerase chain reaction (RT-PCR). TIMP activity and mRNA levels were evaluated by reverse zymography and RT-PCR. Data were analyzed using ANOVA.

RESULTS

Increasing concentrations of L-NMMA produced a dose-dependent decrease in NO(x) (2214 +/- 405 to 347 +/- 37 ng/mg, P < 0.001). Zymography demonstrated a dose-dependent increase in 92-kDa MMP (pro-MMP-9) activity (P < 0.001) with corresponding increases in pro-MMP-9 protein (P = 0.03) and mRNA levels (P = 0.004). While there was a dose-dependent increase in 72-kDa MMP (pro-MMP-2) activity (P = 0.001), pro-MMP-2 protein and mRNA levels were unchanged. Reverse zymography demonstrated a dose-dependent increase in 29-kDa TIMP-1 activity (P = 0.01), but there was no change in TIMP-1 mRNA levels.

CONCLUSIONS

NOS inhibition in ex vivo aortic tissue causes a dose-dependent increase in MMP-9 expression and activity. It is speculated that deficiencies of NO in vivo alter MMP and TIMP homeostasis, favoring matrix degradation.

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.

Organ culture of arteries for experimental studies of vascular endothelium in situ

The objective of this study was to determine whether organ culture of arteries could be used as a more physiological model than endothelial cell culture for the study of vascular endothelium in vitro. Small pieces of artery from rat, pig, piglet and man were cultured in 24-well plates for up to seven or eight days to study the characteristics of the vascular endothelial cell layer during the first week of culture, in particular its integrity, viability and propensity for cell division. Using conventional and confocal microscopy, silver-stained endothelial cell boundaries were shown to be intact at all time points, up to and including day 7. However, occasional very small gaps between endothelial cells were seen with the scanning electron microscope under high power at day 7. Using the bromodeoxyuridine technique, no endothelial cell division was seen at day 4 in any species, except for the occasional endothelial cell in rat aorta. At day 7, pig, piglet and human arteries showed only very occasional dividing endothelial cells, but many endothelial cells had divided by day 7 in rat aorta. Viability of the endothelium was assessed using fluorochromes and examination of the endothelial layer en face using confocal microscopy. Viability was always excellent (> 95%) up to day 4. By day 7, occasional patches of dead cells could be seen, which were most obvious in rat aorta. This study demonstrates that endothelial cells can be studied in situ in organ culture with intact morphology, lack of cell division and excellent viability for a minimum of four days. For many research questions involving vascular endothelium--for example the pathophysiology of hyperacute rejection--short-term organ culture of vessels is likely to represent a more physiological model than endothelial cell culture.

Differentiated properties and proliferation of arterial smooth muscle cells in culture

The smooth muscle cell is the sole cell type normally found in the media of mammalian arteries. In the adult, it is a terminally differentiated cell that expresses cytoskeletal marker proteins like smooth muscle alpha-actin and smooth muscle myosin heavy chains, and contracts in response to chemical and mechanical stimuli. However, it is able to revert to a proliferative and secretory active state equivalent to that seen during vasculogenesis in the fetus, and this is a prerequisite for the involvement of the smooth muscle cell in the formation of atherosclerotic and restenotic lesions. A similar transition from a contractile to a synthetic phenotype occurs when smooth muscle cells are established in culture. Accordingly, an in vitro system has been used extensively to study the regulation of differentiated properties and proliferation of these cells. During the first few days after seeding, the cells are reorganized structurally with a loss of myofilaments and formation of a widespread endoplasmic reticulum and a prominent Golgi complex. In parallel, they lose their contractility and instead become competent to divide in response to a large variety of mitogens, including platelet-derived growth factor (PDGF) and basic fibroblast growth factor (bFGF). After entering the cell cycle, they start to produce these and other mitogens on their own, and continue to replicate in the absence of exogenous stimuli for a restricted number of generations. Furthermore, they start to secrete extracellular matrix components such as collagen, elastin, and proteoglycans. The mechanisms that control this change in morphology and function of the smooth muscle cells are still poorly understood. Adhesive proteins such as fibronectin and laminin apparently have an important role in determining the basic phenotypic state of the cells and exert their effects via integrin receptors. The proliferative and secretory activities of the cells are influenced by a multitude of growth factors, cytokines, and other molecules. Although much work remains before an integrated view of this regulatory machinery can be achieved, there is no doubt that the cell culture technique has contributed substantially to our knowledge of smooth muscle differentiation and growth. At the same time, it has been crucial in exploring the role of these cells in vascular disease and developing new therapeutic strategies to cope with major causes of human death and disability.

Comparison of response to injury in organ culture of human saphenous vein and internal mammary artery

Autologous saphenous vein grafts, unlike internal mammary artery grafts, suffer many late occlusions as a result of excessive proliferation of vascular smooth muscle cells and the superimposition of atheroma on the resulting thickened intima. We investigated the possible basis of this difference using organ cultures. Internal mammary artery segments and freshly isolated and surgically prepared saphenous vein segments were obtained from patients undergoing coronary artery bypass grafting. Internal mammary artery and freshly isolated vein segments showed a high degree of endothelial coverage and medial cell viability that were maintained during culture. Surgically prepared veins showed partial endothelial denudation and medial cell injury, both of which tended to be reversed during culture. Neointimal thickening was greater in surgically prepared vein (72 +/- 13 microns; n = 11) than in freshly isolated vein (44 +/- 8 microns; n = 10) or internal mammary artery (34 +/- 4 microns; n = 13) segments. The occurrence of proliferating cells in the medial layer was also significantly greater in surgically prepared vein (2.8 +/- 1.0/mm; n = 11) than in freshly isolated vein (0.8 +/- 0.3/mm; n = 9) or internal mammary artery (0.6 +/- 0.3/mm; n = 10) segments. The data show that although the smooth muscle proliferation was similar in undamaged saphenous vein and internal mammary artery, it was significantly greater in damaged vein. This implies that the greater intimal proliferation seen in saphenous vein grafts may arise not from intrinsic differences in arterial and venous smooth muscle cells but from a greater susceptibility to injury.

Winner of the ESVS prize 1990. Smooth muscle cell proliferation in response to injury in an organ culture of human saphenous vein

The principal cause of late vein graft occlusion is intimal smooth muscle cell proliferation, the underlying basis of which remains an enigma. Early theories implicating platelet activation now appear untenable since intimal proliferation progresses after endothelial repair, and is little influenced by antithrombotic treatments. We developed an organ culture of human saphenous vein to investigate the basis of intimal proliferation in a preparation which preserved the anatomical relationships of endothelium, smooth muscle and extracellular matrix. Tissue viability remained high during culture for up to 14 days and intimal smooth muscle proliferation occurred. The removal of endothelium reduced intimal thickening in cultured veins from 26 +/- 5 to 6 +/- 3 microns and also reduced the number of intimal cells/mm labelled with [3H]-thymidine from 12 +/- 4 to 3 +/- 1 (both p less than 0.01, n = 10). Surgical preparation of vein resulted in significant injury to medial smooth muscle cells, which was only partially reversed during culturing. Surgical preparation did not affect intimal proliferation, but stimulated medial proliferation from 3 +/- 1 to 32 +/- 9 [3H]-thymidine-labelled cells/mm (p less than 0.01, n = 11). These experiments reveal evidence for proliferation enhancing factors derived from endothelium and injured smooth muscle cells, which probably participate in intimal proliferation in vein grafts. Inhibiting their action may therefore present new possibilities for therapy.

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.

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

Segments of rat carotid artery were maintained in serum-free or serum-supplemented medium for 2 wk, and at intervals of 3, 7, and 14 d the morphology and pattern of matrix synthesis were compared to those in vivo. In serum-free medium and 0.2% serum both the endothelium and the smooth muscle cells (SMC) could be maintained with a minimum of change for 7 d and without substantial change for 14 d. In 2% and 10% serum there was little change for the first 3 d, but subsequently there was a progressive overlapping of the endothelial cells to produce a 3 to 4 layered cell sheet, often separated from the subendothelial matrix; the SMC, however, did not appear to proliferate or migrate and in general retained their typical cellular features for the full time in culture. The synthesis of matrix components was measured by autoradiographic detection of incorporated [H]glucosamine and 35S. At all time periods and serum concentrations the percentage distribution for each label across the arterial wall was found to be similar to that in live animals injected with the same labels. [3H]Glucosamine predominated in the endothelium and the narrow subendothelial layer, which together make up the intima, whereas 35S predominated in the media. In vitro more than 50% of the [3H]glucosamine in the intima and 40% in the adjacent first layer of the media was susceptible to Streptomyces hyaluronidase. As the morphology of both cell types and their synthesis of matrix components could be maintained in organ culture without substantial change we believe that the rat carotid artery may be a suitable model for the investigation of factors affecting arterial structure.

Histotypic angiogenesis in vitro: light microscopic, ultrastructural, and radioautographic studies

A model for the study of angiogenesis in vitro is described. Rat aortas, cultured in a tridimensional matrix of clotted chick plasma, gave rise to luxuriant outgrowth of vascular channels. We studied this process with light microscopic, radioautographic, and ultrastructural techniques. On the 2nd d of culture, endothelial cells sprouted from the intima of the aorta and its collateral branches into the surrounding clot, forming solid cellular cords. A complex vascular network was established within the 1st wk by spindly, poorly differentiated endothelial cells. At this stage cells were migrating, branching, and proliferating in a longitudinal fashion (labeling index: 67.4% +/- 7.7). Lumens, when present, appeared as slitlike spaces enclosed with junctional complexes. By the end of the 2nd wk the migratory activity decreased and proliferation occurred mostly in a cross-sectional plane, with formation of large patent lumens (labeling index: 48% +/- 3.1). Vascular channels were lined by prominent endothelial cells rich in rough endoplasmic reticulum, polysomes, mitochondria. Golgi apparatuses, and coated vesicles. Cells were enveloped with a ruthenium red positive layer, particularly abundant on the luminal surface and in the interendothelial space. A discontinuous basal lamina was present along the abluminal side. At 28 d the labeling index was reduced to 2.25% +/- 0.9. The still viable endothelium exhibited numerous microfilaments and microtubules, decreased cytoplasmic organelles, and increased pinocytotic activity. This experimental model, histophysiologic gradient culture, provides us with a new tool for the study of vascular morphogenesis, angiogenesis dependent growth of tumors, and neoplastic intravasation.

Long-term culture of human aortas. Development of atherosclerotic-like plaques in serum-supplemented medium

Segments of human thoracic aorta were maintained in long-term explant culture for 18 weeks in serum-supplemented medium. The aortas were grossly normal in appearance, and random samples fixed for light microscopy prior to culture revealed a normal morphology. The intima contained no more than five layers of smooth muscle cells. After 7 days in culture, the intima was noticeably thicker than the uncultured segments. The increased thickness was due to proliferating smooth muscle cells and production of extracellular material. After several months in culture, extracellular material consisting of collagen and flocculent material was present in areas resembling atherosclerotic fibrous plaques. A peripheral growth, which formed around the explant, was composed of fibroblastlike cells and added to the overall thickness of the intima. However, aortic segment maintained for up to 2 months in serum-free culture medium showed no cellular proliferation. This study demonstrates that changes resembling early stages of atherosclerosis occur in human aortas maintained in explant culture using routine culture procedures.