Microvascular pericytes contain muscle and nonmuscle actins

Alpha 1-antichymotrypsin is present together with the beta-protein in monkey brain amyloid deposits

The recent finding that the serine protease inhibitor, alpha 1-antichymotrypsin, is tightly associated with the amyloid deposits in brains of normal aged individuals and patients with Alzheimer's disease [Abraham C. R., Selkoe D. J. and Potter H. (1988) Cell 52, 487-501], suggests a role for this inhibitor in the progressive deposition of brain amyloid in humans. We have used immunocytochemistry to detect alpha 1-antichymotrypsin in the amyloid that accumulates in brains of aged monkeys, a naturally occurring animal model of Alzheimer-like neuropathology. In monkeys of increasing age, the earliest alpha 1-antichymotrypsin immunoreactivity was found in cortical perivascular cells, before the appearance of either Thioflavin S-detectable amyloid deposits or beta-protein reactivity in the vessel walls. Subsequently, amyloid deposits appeared in small meningeal blood vessels and cortical neuritic plaques. The oldest monkeys also showed microvascular amyloid in the cortical gray matter. Amyloid was never seen in white matter. The amyloid deposits in meningeal vessels were always positive for both beta-protein and alpha 1-antichymotrypsin, whereas in the cortex, alpha 1-antichymotrypsin immunoreactivity seemed to appear somewhat later than that of beta-protein. These findings demonstrate that two of the brain amyloid components of human senescence and Alzheimer's disease--the beta-protein and the protease inhibitor alpha 1-antichymotrypsin--are also present in the amyloid deposits of normal aged monkey brain. The extended molecular parallels between normal brain aging and Alzheimer's disease suggest that similar biochemical mechanisms may underlie progressive amyloid deposition in both situations.

Tumor-related angiogenesis

In recent years, tumor-related angiogenesis has become an important field of research in oncology. It could be stated that growth of solid tumors is completely dependent on neovascularization to provide the tumor with all required nutrients. Special compounds (tumor angiogenesis factor[s]) are released by tumor cells into the environment to stimulate different types of normal cells to become active for the tumor. In particular, endothelial cells of neighboring capillaries are induced to react. They disintegrate their own basal lamina, detach from their neighbors, enter the extracellular matrix, and migrate toward the tumor mass. Cell divisions occur within such sprouts, thereby increasing the number of migrating endothelial cells. Strands of such cells are formed, and inter- and intracellular lumina develop. Loops of these hollow strands anastomose to form a network of new vessels which become connected with the blood circulation. The tumor mass thus becomes vascularized and can continue to grow. The prevention of neoangiogenesis has an enormous impact on cancer treatment by inhibiting the growth of the tumor. In this review, all important aspects of tumor-related angiogenesis are presented.

Aldose reductase and polyol in cultured pericytes of human retinal capillaries

Aldose reductase has been found in several tissues involved in the various complications of long-term diabetes. Since the loss of intramural pericytes is typical of early microangiopathy of the diabetic retina, the presence of aldose reductase and its activity were investigated in pericytes cultured from capillaries of human retinas. Verification that contaminating cells had been removed was made on the basis of the pericytes' distinctive appearance in culture, inability to internalize acetylated-low-density lipoprotein, and immunoreactivity for muscle actin. Using pure cultures of human pericytes, the presence of aldose reductase was demonstrated immunohistochemically with antibodies directed against human placental aldose reductase, and aldose reductase activity was shown biochemically by monitoring the accumulating of xylitol in cells incubated with xylose. Xylitol accumulation was inhibited by the inclusion of an aldose reductase inhibitor in the xylose-containing medium.

Modulation of human aorta smooth muscle cell phenotype: a study of muscle-specific variants of vinculin, caldesmon, and actin expression

Vinculin- and caldesmon-immunoreactive forms and actin isoform patterns were studied in samples of normal and atherosclerotic human aorta. After removal of adventitia and endothelium, the remaining tissue was divided into three layers: media, muscular-elastic (adjacent to media) intima, and subendothelial (juxtaluminal) intima. In media of normal aorta, meta-vinculin accounted for 41.0 +/- 0.9% (mean +/- SEM) of total immunoreactive vinculin (meta-vinculin + vinculin); 150-kDa caldesmon accounted for 78.2 +/- 5.1% of immunoreactive caldesmon (150-kDa + 70-kDa); the fractional contents of alpha-smooth muscle actin, beta-nonmuscle, and gamma-isoactins were 49.0 +/- 0.6%, 30.4 +/- 0.6%, and 20.8 +/- 0.8%, respectively. Muscular-elastic intima was very similar to media by these criteria. In subendothelial intima, the fractional content of meta-vinculin and 150-kDa caldesmon was significantly lower (6.9 +/- 1.5% and 32.7 +/- 7.0%, respectively) than in muscular-elastic intima and media, whereas the isoactin pattern was identical to that in adjacent layers, demonstrating the smooth muscle origin of subendothelial intima cells. In atherosclerotic fibrous plaque, the fractional content of alpha-actin was decreased in subendothelial intima, rather than in media and muscular-elastic intima. Additionally, the proportion of subendothelial intima cells [i.e., the cells that express low amounts of smooth muscle phenotype markers (meta-vinculin, 150-kDa caldesmon, and alpha-actin)] in the total intima cell population increased dramatically in atherosclerotic fibrous plaque. The results suggest that changes in the relative content of meta-vinculin and 150-kDa caldesmon as well as alpha-actin in human aortic intima are associated with atherosclerosis although, in subendothelial intima of normal aorta, a certain smooth muscle cell population exists that expresses reduced amounts of "contractile" phenotype markers, even in the absence of the disease.

Preferential expression of a 130,000-Da cell surface protein by vascular wall cells in vitro and in vivo

Monoclonal antibodies have been raised against cell surface proteins of cultured bovine retinal pericytes. One antibody was selected, designated PC4, which preferentially stained primary cultures of bovine pericytes and smooth muscle cells, but not endothelial cells and fibroblasts. In freshly plated cells a homogeneous cell surface staining was observed, whereas in well-spread cells the antigen was concentrated at cell attachment sites. The antigen remained at these sites after spontaneous detachment of the cells. PC4 monoclonal antibodies reacted with a major protein of 130,000 Da and two minor antigens of 75,000 and 70,000 Da in immunoblots of extracts from cultured pericytes and smooth muscle cells and from fibroblasts cultured for an extended period of time. In frozen sections of bovine tissues the antigen was found in the vascular wall. There was no staining of skeletal muscle cells or duodenal smooth muscle cells, indicating that the antigen may be a specific component of the vascular wall.

Venular endothelium in vitro: isolation and characterization

The structural and functional properties of the endothelium vary in relation to anatomic site and position along the vascular tree. Cultures of endothelial cells have been obtained so far from large arteries, large veins and capillaries, but not from venules. We now report techniques for culturing not only rat arterial and venous endothelium, but also a special method for obtaining and culturing venular endothelium. The technique is based on the principle of "vascular labeling," whereby an insoluble pigment can be permanently deposited in the wall of the venules, making them easily visible by light microscopy. The venules of a rat cremaster muscle are labeled with a local injection of histamine followed by Monastral blue B intravenously (i.v.); 24 hours later selected venules are isolated by microdissection and either enzymatically dispersed or placed directly into tissue culture wells. The wells are coated with fibronectin and laminin and supplemented with DMEM, 20% fetal calf serum, and endothelial cell growth factor. Polygonal and spindly endothelial cells begin as clusters, grow in sheets, and sometimes form tubes. The cells stain variably for Factor VIII-related antigen, Ulex Europeus I lectin, and non-muscle specific actin. They synthesize angiotensin-converting enzyme, but do not metabolize acetylated LDL. Ultrastructurally, they display pinocytic vesicles, microtendons, and tight junctions, but not Weibel-Palade bodies. We believe that this method will be important for studying the pathophysiology of venules, which are the preferential target of inflammatory mediators and the typical site of inflammatory cell diapedesis.

Vasoactive hormones and cAMP affect pericyte contraction and stress fibres in vitro

Pericytes are contractile cells of the microvascular wall that may influence capillary haemodynamics and permeability. We examined the contractile responses of cultured pericytes to selected vasoactive agents and cAMP agonists. Morphological and biochemical changes associated with these responses were also studied. Pericytes seeded onto silicone rubber contracted when stimulated with histamine or serotonin, relaxed in response to the beta-adrenergic agonist isoproterenol and did not respond to epinephrine. Since hormonal-induced relaxation of vascular smooth muscle involves cAMP, we investigated the ability of cAMP, to modulate pericyte contraction. Dibutyryl cAMP and forskolin (an adenylate cyclase activator) both induced pericyte relaxation and elevated intracellular cAMP levels. Isoproterenol increased cAMP levels but epinephrine had no effect. However, when epinephrine and isoproterenol were co-incubated with the phosphodiesterase inhibitor 3-isobutyl-1-methylxanthine (IBMX), cAMP was increased to levels above those elicited by these agonists alone. Serotonin and histamine in the presence of IBMX did not affect cAMP levels. These results suggest that certain vasoactive agents may relax pericytes by cAMP-dependent processes. We have shown previously that stress fibres are also involved in pericyte contraction. Hence, changes in the staining patterns of stress fibres in response to these selected agonists were studied. Histamine, serotonin and epinephrine had no apparent effect on stress fibre staining. Dibutyryl cAMP, forskolin, and isoproterenol, which relax pericytes and increase cAMP, disassembled fibres. In summary, the results demonstrate that the contractile activity of cultured pericytes in vitro can be regulated by vasoactive agonists and that changes in cAMP and stress fibres may mediate the regulation.

ATP causes retinal pericytes to contract in vitro

We evaluated the contractility of bovine retinal microvascular pericytes in culture by permeabilizing the cells with 0.1% Triton X-100 and measuring their response to MgATP. Sequential photographs of the cells were taken over 20 min and their surface areas were measured. Our study directly demonstrates that pericytes are contractile cells, which respond to MgATP in a dose-dependent fashion over a relatively short time course (minutes). Pericytes did not contract in response to GTP, pyrophosphate or beta, gamma-methylene ATP. Immunofluorescence study showed the presence of muscle actin in Triton X-100-treated cells before and after contraction, indicating preservation of this cytoskeletal protein even after treatment with the detergent. Similar experiments on human umbilical vein endothelial cells, bovine lens epithelial cells and human retinal pigment epithelial cells showed that these cells were significantly less contractile than retinal pericytes. That pericytes show substantial contraction over a short time course indicates that these cells may play a major role in regulating blood flow in the microcirculation.

A monoclonal antibody (3G5)-defined ganglioside antigen is expressed on the cell surface of microvascular pericytes

The identification of microvascular pericytes in vitro relies principally on morphological characteristics and growth dynamics, as there is a paucity of immunochemical markers for these cells. Consequently, an attempt was made to identify mAb reagents that would aid in both the rapid identification and enrichment of retinal capillary pericytes in vascular cell cultures. A panel of mAbs raised by xenogeneic immunization of mice with various tissues was screened for immunoreactivity with dissociated cultures of bovine retinal capillary pericytes. Two antibodies from the panel (3G5 and HISL-8) were seen to react with pericytes by indirect immunofluorescence. The mAb 3G5 was selected for further study. mAb 3G5 did not react with dissociated cultures of smooth muscle cells, endothelial cells, or retinal pigmented endothelial cells. The pericyte 3G5 antigen was insensitive to the action of trypsin; therefore, mAb 3G5 was used to selectively purify pericytes from trypsinized mixed retinal cell cultures by flow cytometry. 3G5+ pericytes (representing 8% of cells in a mixed retinal cell culture) were enriched at least nine-fold to represent greater than 70% of cells. The mAb 3G5 stained retinal capillaries in vivo with a fluorescence distribution consistent with pericyte staining. The 3G5 antigen of cultured pericytes was found to be a glycolipid of mobility intermediate between ganglioside markers GM1 and GM2.

In situ analysis of microvascular pericytes in hypertensive rat brains

We used immunofluorescence microscopy and isoactin-specific antibodies to characterize the pattern and prevalence of pericytes within the brain microcirculation. Blood pressures of normotensive, Wistar-Kyoto (WKY) and spontaneously hypertensive (SHR) rats were measured prior to sacrifice and pressure-perfusion fixation. WKY and SHR brains were subdivided into ten major regions prior to ultracryomicrotomy. Sections 0.3-0.5 micron wide were treated with 10-40 micrograms/ml affinity-purified antibodies to the muscle and non-muscle actin isoforms. These localization studies show that there are four times the number of pericyte-rich capillaries in the SHR motor cortex compared to WKY counterparts (59.9 vs. 15.3%). In contrast, the sensory cortex of both rat strains is deficient in muscle actin staining surrounding the capillaries. The most striking difference in pericyte presence and muscle actin antibody staining between the SHR and WKY was observed in the tegmentum of the brainstem. There is nearly a one-to-one coincidence observed in pericyte and capillary profiles present within thin, frozen sections of the SHR midbrain. SHR pons capillaries were also pericyte-enriched. WKY analyses of plastic embedded thin sections confirmed the presence of pericytes and their filament-enriched processes encircling the capillaries of the hypertensive brains. These results suggest that pericytes may play important roles in hypertension and cerebrovascular disease processes.

Size-dependent hyaluronate degradation by cultured cells

Hyaluronate degradation was examined in cultures of vascular wall cells (bovine aortic endothelial cells, rat aortic smooth muscle cells) and in nonvascular cells (chick embryo fibroblasts). The three cell types examined all produced hyaluronidase activity in culture which had a strict acidic pH requirement for activity. This suggested that the enzyme was active only within an acidic intracellular compartment and therefore that hyaluronate degradation occurred at an intracellular site. This was supported by the observation that the presence of hyaluronidase activity alone was not sufficient to ensure degradation of extracellular hyaluronate. Rather, the key limiting factor in this process appeared to be hyaluronate internalization, and this was found to be hyaluronate size-dependent and to a degree, cell-specific. The relationship of these results to morphogenesis and tissue remodeling is discussed.

Characterization of stromal cells with myoid features in lymph nodes and spleen in normal and pathologic conditions

Stromal cells with myoid features were identified in rat or human lymph nodes and spleen in normal and pathologic conditions, using antibodies to desmin, alpha-smooth muscle actin, and smooth muscle myosin. In normal lymph nodes, myoid cells (MCs) were present in the superficial and deep paracortex as well as in the medulla, and absent in lymphoid follicles. In the spleen, they were numerous in the red pulp, less abundant in periarteriolar lymphocyte sheaths of the white pulp, and absent in lymphoid follicles. On double immunostaining, alpha-smooth muscle actin and smooth muscle myosin were coexpressed with desmin only in the deep paracortex and parafollicular areas of the lymph nodes, as well as in the MCs of the periarteriolar lymphocyte sheaths and marginal zone of the spleen; the remaining MCs expressed only desmin. When examined by means of electron microscopy, MCs showed a dendritic shape and cytoplasmic bundles of microfilaments with dense bodies scattered between them. When compared with normal conditions, MCs showed changes of distribution and number in several pathologic situations. Additional findings were 1) staining of pericytes surrounding high endothelium venules of lymph nodes with alpha-smooth muscle actin antibodies in man and rat and with desmin antibodies in rats; 2) staining of endothelial cells in these venules with desmin antibodies in rats. It is concluded that a subset of reticular cells in lymph nodes and spleen, as well as pericytes and endothelial cells in high endothelium venules display cytoskeletal features suggesting a myoid differentiation and function.

In situ localization of F-actin microfilaments in the vasculature of the porcine retina

The organization of F-actin microfilaments in the vascular endothelium of the porcine retina was studied in situ using rhodamine phalloidin labelling and fluorescence microscopy. A comparison was made between arterial and venous endothelial-cell microfilament distribution. The arterial cells in straight segments, bifurcations and branch points were elongated with their long axis in the direction of flow. Venous endothelial cells, on the other hand, were ellipsoid to rhomboid in shape throughout. F-actin was localized at the periphery of both arterial and venous endothelial cells. Prominent central microfilament bundles, similar to in vitro stress fibres, were oriented parallel to the long axis of arterial cells but were rarely present in venous cells. Only occasional venous endothelial cells contained short central actin filaments which were mainly in the venules. Central microfilaments were not identified in pre-capillary, capillary, or post-capillary endothelial cells. Incubation of the retinal organ cultures for 24 hr resulted in loss of the central microfilaments while peripheral staining persisted. Short-term incubation of the retinas in organ culture with low-dose cytochalasin B resulted in disruption of the central microfilaments while the peripheral actin microfilaments remained intact. The central microfilament bundles may reflect an adaptive response to arterial blood flow and may indeed be a sensitive dynamic system reflecting the influence of environmental factors on endothelial cells.

Inhibition of capillary endothelial cell growth by pericytes and smooth muscle cells

Morphological studies of developing capillaries and observations of alterations in capillaries associated with pathologic neovascularization indicate that pericytes may act as suppressors of endothelial cell (EC) growth. We have developed systems that enable us to investigate this possibility in vitro. Two models were used: a co-culture system that allowed direct contact between pericytes and ECs and a co-culture system that prevented physical contact but allowed diffusion of soluble factors. For these studies, co-cultures were established between bovine capillary ECs and the following growth-arrested cells (hereafter referred to as modulating cells): pericytes, smooth muscle cells (SMCs), fibroblasts, epithelial cells, and 3T3 cells. The modulating cell type was growth arrested by treatment with mitomycin C before co-culture with ECs. In experiments where cells were co-cultured directly, the effect of co-culture on EC growth was determined by comparing the mean number of cells in the co-cultures to the mean for each cell type (EC and modulating cell) cultured separately. Since pericytes and other modulating cells were growth arrested, any cell number change in co-cultures was due to EC growth. In the co-cultures, pericytes inhibited all EC proliferation throughout the 14-d time course; similar levels of EC inhibition were observed in SMC-EC co-cultures. Co-culture of ECs with fibroblasts, epithelial cells, and 3T3 cells significantly stimulated EC growth over the same time course (30-192% as compared to EC cultured alone). To determine if cell contact was required for inhibition, cells were co-cultured using Millicell chambers (Millipore Corp., Bedford, MA), which separated the cell types by 1-2 mm but allowed the exchange of diffusible materials. There was no inhibition of EC proliferation by pericytes or SMCs in this co-culture system. The influence of the cell ratios on observed inhibition was assessed by co-culturing the cells at EC/pericyte ratios of 1:1, 2:1, 5:1, 10:1, and 20:1. Comparable levels of EC inhibition were observed at ratios from 1:1 to 10:1. When the cells were co-cultured at a ratio of 20 ECs to 1 pericyte, inhibition of EC growth at 3 d was similar to that observed at other ratios. However, at higher ratios, the inhibition diminished so that by the end of the time course the co-cultured ECs were growing at the same rate as the controls. These results suggest that pericytes and SMCs can modulate EC growth by a mechanism that requires contact or proximity. We postulate that similar interactions may operate to modulate vascular growth in vivo.

Isolation and culture of cells derived from human cerebral microvessels

Microvessels were isolated from non-neoplastic human cerebral cortical fragments resected for treatment of intractable seizure disorder. The microvessels were incubated in modified Lewis medium with 20 or 30% fetal bovine serum. Within 1-2 weeks, two cell populations emerged from the isolates. One type of cells had polygonal morphology, showed density-dependent contact inhibition at confluence in vitro, showed lectin-binding characteristics of endothelium (but only moderate positivity for factor VIII antigen), demonstrated induction of gamma-glutamyl transpeptidase when exposed to astrocyte-conditioned media, and responded to insulin by a pronounced increase in DNA synthesis. The other variety of cells grew in vitro more slowly in irregular strands separated by clear zones, showed ultrastructural features of smooth muscle, and isoelectric focusing of cell proteins revealed the presence of smooth-muscle-specific alpha-isoactin. Both types of cells could be serially subcultured. The ability to isolate and grow the two cell types, tentatively identified as human cerebral microvascular endothelium and smooth muscle, may facilitate studies of human blood-brain barrier function as well as the pathogenesis of cerebral microangiopathies unique to the human brain.

Junctional transfer of small molecules in cultured bovine brain microvascular endothelial cells and pericytes

We have utilized cultures of bovine brain microvascular endothelial cells (MEC) and pericytes to study two aspects of intercellular relations in the microvasculature. First, the apparent contradiction between the reported demonstration of dye transfer between endothelial cells in capillaries and venules in rat omentum and the lack of ultrastructurally demonstrable interendothelial gap junctions in the same vessels in omentum, brain, and other tissues led us to examine this problem in vitro. MEC showed extensive transfer of both fluorescent dye (Lucifer yellow CH, 96% transfer incidence in primary culture) and radiolabeled uridine nucleotides (97%). Freeze-fracture replicas of MEC revealed both gap and tight junctions. These results demonstrate that MEC are capable of producing gap junctions and engaging in junctional communication in vitro. Second, we have examined the interaction of pericytes with MEC. Cultured pericytes showed gap junctions in freeze-fracture replicas, variable dye transfer (cell density dependent, 19-91%), and extensive nucleotide transfer (94%). While the incidence of dye transfer between MEC and pericytes was low (10-31%), nucleotide transfer between these cells was extensive (86-96%). The demonstration of junctional transfer between MEC and pericytes in vitro may be particularly significant considering the high frequency of junctional contact between these cells in vivo. These cultured cell models should help us to better understand the complex interactions of vessel wall cells in microvascular physiology and pathophysiology.

Characteristics of lung pericytes in culture including their growth inhibition by endothelial substrate

Pericytes and endothelial cells from the same sample of adult rat lung have been separately established in culture by use of selective growth media. The endothelial cells are positive and the pericytes negative for angiotensin-converting enzyme activity and tissue plasminogen activator. Morphologically in culture, the pericytes are similar to pericytes from bovine retina and other sites and show positive immunofluorescence to both human platelet (non-muscle) myosin and smooth muscle myosin. In this respect they resemble smooth muscle cells grown from the rat main pulmonary artery, but lack the myofilaments and dense bodies characteristic of muscle cells. Lung endothelial cells and fibroblasts are positive only for platelet myosin. Pericytes in culture demonstrate an unusual growth response to endothelial substrate, obtained by removing confluent endothelial monolayers with nonionic detergent or alkali. When plated onto this material at low density, pericyte growth is inhibited. By contrast, the substrate stimulates the growth of endothelial cells and has no effect on smooth muscle cells. Initial attachment of endothelial cells and pericytes to the substrate is similar.

Microvascular pericyte contractility in vitro: comparison with other cells of the vascular wall

Collagen lattices containing bovine retinal pericytes (RPs), vascular smooth muscle cells (VSMCs), pulmonary microvessel endothelial cells (PMECs), or aortic endothelial cells (AECs) were prepared and contraction was quantitated by measuring the resulting change in lattice area. VSMCs were the most efficient at lattice contraction followed by RPs and then PMECs. AECs did not contract the lattices. To document further that these observations represent contraction, cells were grown on inert silicone rubber sheets. Substratum wrinkling was indicative of tension development and quantitated as percent of cells contracted. RPs were more contractile than PMECs, and AECs were incapable of developing tension. VSMCs were less contractile than RPs, unlike the comparative contractility observed with the lattice system. Alteration of actin-containing filaments by cytochalasin B significantly reduced RP contraction of silicone rubber and inhibited their contraction of collagen lattices in a dose-dependent manner. Rhodamine-phalloidin staining of contracting RPs revealed microfilament bundle orientations that suggested their association in the force applied for contraction. RP, VSMC and PMEC contraction of collagen lattices was directly proportional to the concentration of fetal calf serum. Also, RP contraction was greater in calf serum than calf plasma-derived serum, an indication that RPs respond to substances that appear continuously and episodically in blood. These in vitro findings support the theory that pericytes in vivo are contractile but that endothelial cells may also contribute to microvascular tonus.

Effects of hyperoxia on microvascular cells in vitro

Microvascular cells are most vulnerable to direct oxygen damage. Using an in vitro model system we have investigated the effect of elevated oxygen on the proliferation, morphology, and integrity of microvascular endothelial cells (EC) and pericytes. Cultivation of these cells at oxygen concentrations of 40% for 1 wk resulted in the inhibition of EC proliferation but had no effect on the growth of the pericytes. Similarly, hyperoxia induced a dramatic change in the shape of the EC, increasing their spread area by close to six-fold. Under the same conditions, the spread area of the pericytes was unaffected. To understand the effect of the hyperoxic treatment on the cells, the integrity of various membrane systems was assessed. 51Chromium release was used to monitor plasma membrane integrity. There was no difference in chromium release by EC and pericytes over the 7 d of growth under normoxic and hyperoxic conditions. Mitochondrial integrity was examined by staining the cells with Rhodamine 123, which is selectively accumulated by the mitochondria. The staining pattern of the mitochondria of both EC and pericytes was altered by growth in the elevated oxygen. Finally, the lysosomes were visualized using acridine orange. The acridine orange staining pattern revealed enlarged and perinuclear lysosomes in the EC but no change in the pericyte lysosomal staining pattern. Thus, the cells of the microvasculature seem to be differentially affected by hyperoxia, a fact that may be significant in the etiology of reperfusion injury, ischemic disease, and pathologies associated with prematurity.

Characterization of microvascular cell cultures from normotensive and hypertensive rat brains: pericyte-endothelial cell interactions in vitro

We used specific markers and fluorescence microscopy to identify and characterize cerebrovascular cells. Cultures were derived from brain microvessels isolated from normotensive (Wistar Kyoto, WKY) and spontaneously hypertensive (SHR) rat brains prior to, coincident with and following the onset of chronic hypertension. Endothelial cells were characterized using di-acyl LDL and non-muscle isoactin-specific antibodies. Cerebrovascular pericytes were identified with the anti-muscle and non-muscle actin antibody staining. Using this combination of cell culture and fluorescence localization, we have been able to demonstrate that brain pericytes are tightly associated with the endothelial cells of the hypertensive-prone and hypertensive cell cultures, but not with the normotensive endothelial cultures. While the endothelial-pericyte ratio in the hypertensive-prone microvascular cultures was between 5:1 and 10:1, the number of pericytes associated with the hypertensive rat brain cultures increased two to five times (2:1-1:1). Muscle and non-muscle actin antibody staining localized the spindle-shaped pericytes of the hypertensive microvascular colonies. Pericytes were found overlaying and encircling the endothelial cells. Normotensive pericytes were not endothelial-associated. Whereas the hypertensive pericyte is devoid of stress fibers, the normotensive pericyte is a larger, spread-out cell possessing numerous stress fibers rich in muscle and non-muscle actin. These results provide the first evidence that the etiology and inception of cerebrovascular disease may be pericyte-related and suggest that pericyte contraction could play a pivotal role in regulating the flow of blood within the brain microcirculation.

Platelet-derived growth factor-induced alterations in vinculin distribution in porcine vascular smooth muscle cells

Exposure of porcine vascular smooth muscle cells to platelet-derived growth factor (PDGF; 18-180 ng/ml) but not epidermal growth factor (EGF; 30 ng/ml), somatomedin C (SmC; 30 ng/ml), or insulin (10 microM), results in a rapid, reversible, time- and concentration-dependent disappearance of vinculin staining in adhesion plaques; actin-containing stress fibers also become disrupted following exposure of cells to PDGF. Disappearance of vinculin staining from adhesion plaques is also caused by 12-O-tetradecanoyl-phorbol-13-acetate (TPA; 200-400 nM), though the time course of the disappearance of vinculin staining under these conditions takes longer than in cells exposed to PDGF. The PDGF-induced removal of vinculin from adhesion plaques was inhibited in a concentration-dependent fashion by 8-(N,N-diethylamino) octyl-3,4,5-trimethoxybenzoate (TMB-8; 0.25-4 microM) and leupepetin (2-300 microM), and by n-alpha-tosyl-L-lysine chloromethylketone (TLCK; 100 microM) and trifluoperazine (TFP; 2.5 microM). Addition of PDGF to vascular smooth muscle cells caused a rapid, transient increase in cytosolic free calcium, from a basal resting level of 146 +/- 6.9 nM (SEM, n = 62) to 414 +/- 34 nM (SEM, n = 22) as determined using the calcium-sensitive indicator Fura-2 and Digitized Video Microscopy. This increase in cellular calcium preceded the disappearance of vinculin from adhesion plaques and was partially blocked by pretreatment of cells with TMB-8 but not leupeptin. This rise in cytosolic free calcium was found to occur in approximately 80% of the sample population and displayed both spatial and temporal subcellular heterogeneity. Exposure of cells to TPA (100 nM) did not result in a change in cytosolic free calcium. Both PDGF (20 ng/ml) and TPA (100 nM) caused cytosolic alkalinization which occurred after PDGF-induced disruption of vinculin from adhesion plaques, as determined using the pH-sensitive indicator BCECF and Digitized Video Microscopy. PDGF stimulated DNA synthesis and vinculin disruption in a similar dose-dependent fashion. Both could be inhibited by leupeptin or TMB-8. These results suggest that 1) exposure of vascular smooth muscle cells to PDGF is associated with the disruption of vinculin from adhesion plaques, 2) PDGF-induced vinculin disruption is regulated by an increase in cytosolic calcium (but not cytosolic alkalinization), and involves proteolysis; 3) activation of protein kinase C also causes vinculin removal from adhesion plaques but by a calcium-independent mechanism, and 4) the cellular response to PDGF-stimulated increases in cytosolic free calcium is heterogeneous.(ABSTRACT TRUNCATED AT 400 WORDS)

The mechanism of vascular leakage induced by leukotriene E4. Endothelial contraction

This study identifies the microvascular target of leukotriene E4 (LTE4) by vascular labeling with carbon black and establishes the mechanism of its action at the cellular level by electron microscopy. LTE4 and its tripeptide precursor, leukotriene C4 (LTC4) were injected subcutaneously in guinea pigs. With LTE4, venular labeling was intense at 1000 and 100 ng and slight at 10 ng, with extinction at 1 ng. LTC4 induced a ring of labeled venules around a blank central area, suggestive of vasospasm. The nonpeptidyl leukotriene LTB4 induced no labeling. Histamine (1000 ng) induced an area of vascular labeling about equal to that by 1000 ng LTE4, but the labeling of individual venules was more intense. By electron microscopy, LTE4 was found to induce gaps in the endothelium of the venules; the endothelial cells adjacent to the gaps bulged into the lumen and showed wrinkled nuclei, consistent with cellular contraction. This ultrastructural evidence suggests that LTE4 increases vascular permeability by contraction of endothelial cells selectively, in the postcapillary venules, as was previously demonstrated for other inflammatory mediators, including histamine, serotonin, and bradykinin.

A monoclonal antibody against alpha-smooth muscle actin: a new probe for smooth muscle differentiation

A monoclonal antibody (anti-alpha sm-1) recognizing exclusively alpha-smooth muscle actin was selected and characterized after immunization of BALB/c mice with the NH2-terminal synthetic decapeptide of alpha-smooth muscle actin coupled to keyhole limpet hemocyanin. Anti-alpha sm-1 helped in distinguishing smooth muscle cells from fibroblasts in mixed cultures such as rat dermal fibroblasts and chicken embryo fibroblasts. In the aortic media, it recognized a hitherto unknown population of cells negative for alpha-smooth muscle actin and for desmin. In 5-d-old rats, this population is about half of the medial cells and becomes only 8 +/- 5% in 6-wk-old animals. In cultures of rat aortic media SMCs, there is a progressive increase of this cell population together with a progressive decrease in the number of alpha-smooth muscle actin-containing stress fibers per cell. Double immunofluorescent studies carried out with anti-alpha sm-1 and anti-desmin antibodies in several organs revealed a heterogeneity of stromal cells. Desmin-negative, alpha-smooth muscle actin-positive cells were found in the rat intestinal muscularis mucosae and in the dermis around hair follicles. Moreover, desmin-positive, alpha-smooth muscle actin-negative cells were identified in the intestinal submucosa, rat testis interstitium, and uterine stroma. alpha-Smooth muscle actin was also found in myoepithelial cells of mammary and salivary glands, which are known to express cytokeratins. Finally, alpha-smooth muscle actin is present in stromal cells of mammary carcinomas, previously considered fibroblastic in nature. Thus, anti-alpha sm-1 antibody appears to be a powerful probe in the study of smooth muscle differentiation in normal and pathological conditions.

Surface-associated vesicles in retinal arterioles and venules

The surface-associated vesicles in retinal arterioles and venules were studied after fixation in glutaraldehyde-tannic acid or after intravitreal injection of peroxidase or lactoperoxidase. The vesicles were concentrated along the abluminal (basal) surface of the endothelial cells and along the plasma membranes of smooth muscle cells in arterioles and of pericytes in post-capillary venules. They were rarely encountered in the deeper regions of these cells. In perpendicular sections through the cell surface the majority of vesicles were in continuity with the plasma membrane whereas in tangential sections, they appeared to lie "free" in the cytoplasm. All such vesicles were labeled after exposure to tannic acid or to the heme-proteins. Peroxidase-reaction product was never seen in the lumen of the vessels. These observations suggest that the surface vesicles in endothelial cells, smooth muscle cells and pericytes are invaginations of the plasma membrane and are thus not involved in the transcytosis or endocytosis of proteins. The vesicles in the latter two cell types may be involved in some aspect of contractility rather than pinocytosis.

The structure of the wall of the rat intraacinar pulmonary artery: an electron microscopic study of microdissected preparations

Rat intraacinar arterial segments that by light microscopy lack a medial muscle layer are capable of constriction and, during pulmonary hypertension, acquire morphologically differentiated smooth muscle. These facts suggest that effector cells of smooth muscle type are present in the normal vessel wall. Studies in the literature, however, fail to agree on their location or even existence. By combining microdissection, step sectioning, and electron microscopy, we have now performed a serial study of six arterial pathways. At its proximal end, the artery has a circumferentially continuous single layer of smooth muscle cells, separated from the endothelium by a fenestrated internal elastic lamina. Myoendothelial junctions are frequent and incorporate basal laminae of both cell types. More distally, the internal elastic lamina is discontinuous and the smooth muscle cells lose myofilaments and dense bodies so as to resemble intermediate cells. They still form a continuous layer, however. At mid-alveolar-duct level, this layer is discontinuous, and in the most distal arteries investigated, the cells are often solitary. They lie close to the endothelial cell, but, except for localized regions of contact, are separated from it by a single basal lamina that is continuous with one covering their abluminal surface.

Actin, myosin, and laminin localization in retinal vessels of the rat

Actin, myosin, and laminin have been localized in retinal vessels of normal rats by fluorescence microscopy. Actin was localized with the fluorescent F-actin binding toxin nitrobenzoxadiazole phallacidin (NBD-Ph). Indirect immunofluorescence was used to localize myosin and laminin. In addition, laminin localization was also performed with the Protein A-horseradish peroxidase (PA-HRP) method. NBD-Ph staining gave strong fluorescence in both retinal capillaries and larger vessels. Anti-myosin fluorescence could also be observed in trypsin digests of the retinal vasculature. Strong fluorescence of PA-HRP reaction product could be detected in the walls of vessels exposed to anti-laminin antibody. Actin distribution in vessels of the RCS rat with inherited retinal degeneration (retinal dystrophic RCS rat) was also studied. After exposure to NBD-Ph, all capillaries showed fluorescence. However, it was more intense in many of the capillaries in the outer retina, which also appeared morphologically abnormal. Electron microscopy of retinal capillaries fixed in 2.5% glutaraldehyde containing 8% tannic acid revealed numerous microfilaments in the pericyte cytoplasm and some in the basal portion of endothelial cells. In pericytes, these microfilaments are in close association with the endothelial side of the cell. Tangential sections through this region indicate that these filaments may be anchored to the membrane at this site.

Immunolocalization of the gamma isoform of nonmuscle actin in cultured cells

In many vertebrate nonmuscle cells, the microfilament subunit protein, actin, exists as two isoforms, called beta and gamma, whose sequences differ only in their amino-terminal regions. We have prepared a peptide antibody specifically reactive with the amino-terminal sequence of gamma actin. This antibody reacted with nonmuscle actin as determined by Western blots of SDS gels, and reacted with the gamma, but not the beta, nonmuscle actin isoform as shown by Western blots of isoelectric focusing gels. In immunofluorescence experiments, the gamma peptide antibody stained microfilament bundles, ruffled edges, and the contractile ring of a variety of cultured cells, including mouse L cells, which have previously been reported to contain only the beta actin isoform (Sakiyama, S., S. Fujimura, and H. Sakiyama, 1981, J. Biol. Chem., 256:31-33). Double immunofluorescence experiments using the gamma peptide antibody and an antibody reactive with all actin isoforms revealed no differences in isoform localization. Thus, at the level of resolution of light microscopy, we have detected the gamma actin isoform in all microfilament-containing structures in cultured cells, and have observed no subcellular sorting of the nonmuscle actin isoforms.

Mechanisms of arterial graft healing. Rapid transmural capillary ingrowth provides a source of intimal endothelium and smooth muscle in porous PTFE prostheses

Endothelial coverage of an exposed synthetic vascular graft surface limits thrombosis and may improve long-term graft performance. In most types of synthetic graft, luminal endothelium is derived from the cut edges of adjacent artery. In this study the authors investigated the possibility that endothelial coverage could also be obtained by ingrowth of capillaries from the outside of the graft. Porous 4-mm polytetrafluorethylene (PTFE; 60 mu internodal distance) grafts were inserted into the aortoiliac circulation of baboons and were retrieved at intervals of up to 12 weeks. Between 1 and 2 weeks after surgery a continuous sheet of cells began to appear on the surface along the entire graft. These cells stained for Factor VIII related antigen, exhibited endothelial morphology by scanning electron microscopy, were associated with capillary orifices at the luminal surface, and covered the entire graft by 4 weeks. Transmural capillaries were observed to connect the graft lumen to extravascular granulation tissue. Despite full coverage of the graft, endothelial cells continued to exhibit increased proliferation (thymidine labeling) at 12 weeks. Smooth muscle cells (pericytes) accompanied capillary endothelium into the graft lumen, exhibited vascular smooth-muscle-specific immunostaining, and proliferated under the luminal endothelium to form intima. These results indicate that under some circumstances capillary endothelium and smooth muscle cells can function in the same manner as large vessel endothelium and smooth muscle and can provide rapid coverage of porous synthetic graft surfaces in contact with the arterial circulation.