A STUDY OF THE STRUCTURE OF SPLENIC SINUSES IN MAN AND IN THE ALBINO RAT WITH THE LIGHT MICROSCOPE AND THE ELECTRON MICROSCOPE

The splenic sinuses in the spleens of 5 human beings and 7 albino rats have been studied in the light microscope and electron microscope after fixation in Dalton's fluid and Palade's fluid and embedding in n-butyl methacrylate. Splenic sinuses are tortuous vascular channels of large but variable diameter which represent the first venous vessels in the spleen and make up almost the entire red pulp in man and in rats. These vessels are composed of reticulo-endothelial cells flattened to endothelial form and sheathed by a netted reticulum. The luminal surface of the endothelium is made highly irregular by delicate and variable cytoplasmic protrusions, slender corridors separating adjacent endothelial cells, anastomotic openings to other sinuses, bulgings of entire cells, and even thrusts of endothelium spanning the sinai lumen. The supporting reticulum presents a well developed latticed appearance in tangential sections of sinuses, but in most cuts is punctate or linear. The reticulum is composed of strands without limiting membranes, which, in substance, are amorphous and resemble basement membrane. Material identical in appearance to the substance of the reticulum may be present in the endothelium, suggesting that the reticulum is formed by endothelial cells. The endothelium also contains deposits of presumed ferritin and hemosiderin. The extreme luminal bulgings of endothelium suggest production of circulating monocytes or lymphocytes by detachment of endothelial cells. Sinuses are patent and collapsed to varying degrees. Patent sinuses are separated by collapsed sinuses and these collapsed sinuses appear to constitute splenic (Billroth) cords.     

Scanning- and transmission electron-microscopic study of lymphatic vessels in the splenic white pulp of the macaque monkey

Summary The fine structure of the lymphatic vessels in splenic white pulp of the macaque monkey was studied by scanning and transmission electron microscopy.Lymphatic vessels were slit-like or widened channels which extended along central arteries and their large branches. The walls of the vessels were very thin in comparison with those of nearby arteries. They were composed only of a layer of endothelium supported by underlying reticular cells. Endothelial cells were mostly ribbon-like and extended along the long axis of the vessels. Perikarya of the endothelial cells were slightly protruded into the lumen. The thin peripheral cytoplasm showed smooth surfaces, except for some tiny processes, especially at boundaries between adjacent cells. The basal surface of the endothelial cells was attached to the lattice of reticular cell processes forming the framework of the white pulp. Basal laminae in strands were intercalated between endothelial cells and reticular cells. Perforations were often seen through the endothelial cell cytoplasm. Lymphocytes or processes of macrophages seen in the perforations were considered to be in migration. Large patent openings through the endothelium were not observed. The wall structure of the lymphatic vessels in the splenic white pulp suggests that lymphocytes in the white pulp may move directly into the lymph flow, in addition to moving into the blood flow via the vascular sinuses.Supported by Research Grant-in Aid from the Ministry of Education, Japan (Grant NO. 56480081).     

Ultrastructure of human spleen in transmission and scanning electron microscope

Despite new information concerning functional morphology of spleen, there are still some inaccuracies mostly regarding the spleen blood circulation. Billroth’s (splenic) cords are formed from three-dimensional network of fibroblastic reticular cells located among branched sinuses. Results from our study using scanning electron microscopy confirm an intimate contact between adjacent reticular cells and erythrocytes. Arterial terminals can be observed in the Billroth’s cords. The wall of sinuses reminds a sieve and it is lined with a special type of endothelium. In electron microscope, endothelial cells look like rods oriented parallel to the longitudinal axis of sinuses. Based on our observations fibroblastic reticular cells change to fixed phagocytes under no circumstances, hence they do not participate in phagocytosis. They may have a recognition function for cells circulating around them. According to our opinion, the open and the closed blood circulation are present in the human spleen simultaneously. Blood flowing in the closed circulation can help “absorption” of extra-vascular liquid and the blood elements into the vascular lumen. Due to sporadic occurrence of smooth muscle cells in the capsule and trabeculae, we assume that human spleen is not a blood reservoir, unlike the spleen in some other animals.     

Growth and morphology of rabbit marginal vessel endothelium in cell culture

A procedure for the isolation and cultivation of endothelium from the marginal vessels of the rabbit ear is described. Endothelial cells, isolated by slow perfusion with a trypsin solution, are cultured in minimal essential medium supplemented with 10% fresh rabbit serum for up to 6 mo. In primary culture, marginal vessel endothelial cells grow in an expanding circular pattern with closely apposed cell membranes. Weibel-Palade bodies, subcellular organelles unique to endothelial cells in situ, are present in both primary and in serially cultivated cells (12 passages). In intact skin, Weibel-Palade (W-P) bodies are observed in the perinuclear cytoplasm in close proximity to the cell membrane facing the vascular lumen. 8-16 tubules of 200 A diameter are present in each body. In primary and subcultured cells, W-P bodies of identical size are seen in the vicinity of the Golgi apparatus and in close proximity to the outer cell membrane. At the optimum serum concentration (10%), a cell doubling time of 72-96 h is observed. When growth in normal rabbit serum and in platelet-poor serum is compared, a slower growth rate is observed in the absence of platelets, suggesting that factors released by platelets affect endothelial cell proliferation. However, addition of crude platelet factor does not substitute for complete serum. Fibroblast growth factor is not mitogenic for rabbit marginal vessel endothelium in vitro.     

Phenotypic differences between red pulp capillary and sinusoidal endothelia help localizing the open splenic circulation in humans

The distribution of capillaries, sinuses and larger vessels was investigated by immunohistology in paraffin sections of 12 adult human spleens using a panel of antibodies. Double staining for CD34 and CD141 (thrombomodulin) revealed that capillary endothelia in the cords of the splenic red pulp and at the surface of follicles were CD34⁺CD141⁻, while red pulp sinus endothelia had the phenotype CD34⁻CD141⁺. Only in the direct vicinity of splenic follicles did sinus endothelial cells exhibit both antigens. Thus, splenic sinuses do not replace conventional capillaries, but exist in addition to such vessels. The endothelium in arterioles, venules and larger arteries and veins was uniformly CD34⁺CD141⁺. Anti-CD34 and anti-CD141 both additionally reacted with different types of splenic stromal cells. Differential staining of capillaries and sinuses may permit a three-dimensional reconstruction of serial sections to unequivocally delineate the “open” and “closed” splenic circulation in humans.     

Alterations of bone marrow sinus endothelium induced by ionizing irradiation: implications in the homing of intravenously transplanted marrow cells.

The endothelium of bone marrow sinuses is a continuous layer which is selective in its cellular transport. It is not known how selective and massive seeding of hemopoietic progenitor cells after intravenous transplantation of marrow cells occurs. We postulate that the conditioning irradiation could disrupt the endothelial barrier, thus permitting the "homing" of progenitor cells to occur. To demonstrate this phenomenon, we irradiated mice with doses ranging from 100-2000 cGy-total body and studied perfusion-fixed marrow by transmission electron microscopy. The major finding was sloughing and denudation of plasma membrane, particularly on the luminal side of endothelium. Membrane vesiculation was also frequently seen in this border. Moreover, dilatation of the perinuclear space and rough endoplasmic reticulum was commonplace and testified to instability and fragility of the membrane system. Focal cytoplasmic swelling of endothelium was seen reflecting increased permissiveness of the endothelial barrier. Endocytosis and phagocytosis were increased in the marrow; and the endothelium, normally quiescent with regard to phagocytosis, was now overtly phagocytic. A dipogenecity of the adventitial layer was increased as hemopoietic function of marrow decreased. The end result of membrane alterations in the endothelium was the appearance of discontinuities in these cells, which form the essential element of bone marrow-blood barrier. Consequent to these discontinuities, the permissiveness of the endothelial barrier was enhanced and those cellular elements, such as mature, nonreticulated erythrocytes that are normally confined to the vascular space, now appeared in large number in the hemopoietic compartment. With low doses, these findings were transient and repair set in by 1-2 weeks. With higher doses, total disruption of marrow-blood barrier occurred and the process did not seem to be repairable. We conclude that the conditioning irradiation before bone marrow transplantation is essential in disrupting the endothelial barrier and permitting large-scale entry of transplanted cells into the hemopoietic compartment.     

Production of soluble P-selectin by platelets and endothelial cells

The distribution of a soluble form of a cell adhesion molecule, P-selectin, in human platelets and cultivated endothelial cells has been studied by enzyme-linked immunosorbent assay (ELISA). The concentration of soluble P-selectin in the blood plasma of healthy donors and patients with abnormal platelet count has also been determined. P-selectin was measured in the Triton X-100 lysate of platelets and endothelial cells (total P-selectin), in the 100,000g supernatant obtained after sedimentation of the membrane fraction from the homogenate of sonicated platelets and endothelial cells (intracellular soluble P-selectin), in the supernatant of activated and nonactivated platelets, and in the culture medium of endothelial cells. A soluble form of P-selectin which did not coprecipitate with the membrane fraction was detected in platelets and accounted for approximately 10% of the total P-selectin. Platelet activation by thrombin, ADP, or a thromboxane A2 analog resulted in the secretion of 30-50% of the intracellular soluble P-selectin. Measurements of P-selectin in endothelial cell culture revealed that endothelium from aorta contained about twofold more P-selectin than endothelium from umbilical vein. Intracellular soluble P-selectin was identified in both types of endothelial cells. In endothelial cells from the umbilical vein this form made up approximately 10% of the total P-selectin. Soluble P-selectin was also detected in the medium of cultivated endothelial cells, where its content correlated with the total cellular P-selectin. Concentration of P-selectin in blood plasma strongly correlated with the platelet count in the blood of healthy donors and patients with thrombocytosis and thrombocytopenia. These data indicate that platelets serve as one of the main source of plasma P-selectin. However, the presence of P-selectin in the plasma of patients with severe thrombocytopenia suggests that endothelium can also be involved in plasma P-selectin production. Thus, in vitro experiments as well as measurements of plasma P-selectin have shown that both platelets and endothelial cells can produce a soluble form of the protein. Platelet-derived soluble P-selectin and plasma P-selectin were shown to react with antibodies against the cytoplasmic domain of P-selectin. These data prove that at least part of soluble P-selectin is produced by synthesis employing special mRNA which lacks the sequence encoding the transmembrane domain, but not by the proteolytic shedding of the extracellular portion of membrane P-selectin.     

Phenotypic identification and development of distinct microvascular compartments in the postnatal mouse spleen.

In this paper we report the development of the sinus network of mouse spleen during the first postnatal month as studied with a set of new rat monoclonal antibodies (mAbs) against mouse splenic endothelial cell subpopulations. One of the new mAbs (IBL-7/1) also stained B-cell lineage cells in the spleen shortly after the birth as confirmed by three-color flow cytometry. This B-cell staining in the primordial follicles vanished by the fourth postnatal week, so that the expression of IBL-7/1 antigen was restricted to the marginal sinus endothelium and some red pulp sinuses and a minor B-cell subset in the spleen, presumably distinct from the follicular B-cell compartment. The other mAb (IBL-9/2) selectively labeled the sinusoids of the deeper part of the red pulp, without any reactivity against hemopoietic cells. The IBL-9/2-reactive cells in newborns appeared as isolated elements throughout spleen, and during the segregation of white and red pulps they formed an extensive network in the red pulp outside the marginal zone. Double-labeling immunofluorescence revealed that most of these sinusoids also stained weakly with IBL-7/1 mAb, whereas the strongly IBL-7/1-positive vessels of this region were IBL-9/2 negative. Neither of these mAbs reacted with the central artery. The comparative phenotypic analysis of the various vascular segments indicates that the splenic sinusoids of the marginal zone and red pulp, respectively, are lined with a heterogeneous array of endothelium. For the precise identification, isolation, and characterization of the possible homing function of these endothelium subsets these region-specific mAbs may be of potential value.     

SEM and TEM study of caprine superficial lymph nodes

The splenic capsule was characteristic, having dense connective tissue. Smooth muscle cells and unmyelinated nerve fibers were observed. Smooth muscle cells were found to be independent of blood vessels in both the capsule and trabeculae. Littoral cells separated the capsule from the subcapsular sinus. Highly branched reticular cells were associated with the sinuses. The cellular components (large and small lymphocytes, plasma and mast cells, and macrophages) of the cortex and medulla were observed and described. No Golgi apparatus was observed in small lymphocytes and two surface types (rough and smooth) were observed on lymphocytes. Russell bodies were not observed in plasma cells. The paracortical postcapillary venule had cuboidal endothelium with microvilli. Two shapes of lymphocytes were seen associated with the endothelium of postcapillary venules.     

Comparative histochemical and electron microscopic studies of the sinus and venous walls of the human spleen with special reference to the sinus-venous connections

Sinus and venous walls of normal human spleens were studied with enzyme histochemical and electron microscopic methods. Particular attention was paid to the connections between sinuses and veins. Histochemically the sinus lining cells revealed a distinct naphthol-AS-acetate-esterase activity but no reaction for alkaline phosphatase. Venous endothelial cells were positive for the latter but negative for the former enzyme. In the sinus-venous junctional area there were no endothelial cells with reactivity for both enzymes. Electron microscopically both the sinus lining cells and the venous endothelial cells could be clearly characterized and therefore easily distinguished from one another on morphological grounds. There were no clear ultrastrural indications of transitional forms between sinus lining cells and venous endothelial cells in the sinus-venous area. According to these findings, sinus lining cells represent a specialized endothelium, but one with practically no morphological similarities to the venous endothelium.     

缺血再灌后血管内皮空泡的形成与内皮的损伤

目的：在活体上探讨缺血再灌后血灌内上细胞损伤及白细胞、血小板与内皮之间粘附的变化。方法：用失血及与再回输血液造成缺血再灌流模型,在高倍显微镜下观察肠系膜微血管内皮损伤及血细胞粘附的变化。结果：缺血再灌后1－3h细静脉、集合毛细血管内出现白细胞、血小板的粘附,血管内皮水肿、管壁增厚,有的血管内皮细胞的胞浆形成圆丘形的空泡,空泡从血管内皮突入管胺、空泡直径10－30μm多出现的细动脉内,在同一根血管内可同时出现几个空泡,大的空泡几科占据血管腔的2／3。结论：缺血再灌后血管内皮水肿及空泡形成,显示内皮细胞的严重损伤。     

The mechanisms of reparative regeneration of venous endothelium

The reaction of endothelial cells of the inferior vena cava in response to freezing-induced lesions has been analysed in the experiments on 34 young adult Kyoto-Wistar normotensive rats. First the de-endothelialized surface is covered with flattened platelets and then, three days after surgery, the endothelium is restored as a result of migration and proliferation of endotheliocytes. The migrating endothelial cells removed the adhered platelets from de-endothelialized surface. The young endothelium was presented by a single layer of strongly elongated endothelial cells whose axis was parallel to the flow of blood. An immature endothelium is characterized by an increased number of endotheliocytes. No essential differences in the reaction of venous and aortic endothelium have been revealed in response to freezing-induced lesions.     

Ultrastructural observations in canine kidneys perfused hypothermically for 7 days in a comparative study of three preservative solutions

To determine the effectiveness of different renal perfusates, a comparison was made of the ultrastructure of canine kidneys perfused hypothermically for 7 days with (i) cryoprecipitated plasma (CPP); (ii) plasma protein fraction (PPF); or (iii) canine serum (CS). Each perfusate contained the reducing agents ascorbic acid and glutathione, and the redox level of the perfusate was maintained by potentiostatic control. Ultrastructural analysis was limited to the renal cortex from needle biopsies taken prior to perfusion, after perfusion, and 1-hr post-transplant.All kidneys failed soon after transplantation—turning dark, apparently from vascular blockage. In the CPP-perfused group some fibrin clotting was observed along with minor glomerular changes. The endothelium appeared continuous but beaded, and the epithelium showed retracted foot processes and/or villous extensions. The tubular areas displayed good cellular preservation. The post-transplant biopsies appeared similar, showing no further fibrin deposition but extensive erythrocyte blockage. In the PPF group, serious glomerular changes were observed after perfusion. Both the endothelium and epithelium lacked characteristic profile, and cytoplasmic inclusions were reduced. A flocculent precipitate was found in both the capillary lumen and the urinary space. The tubular regions in this group appeared to be well preserved. After transplantation, the PPF group showed progressive deterioration in both the renal corpuscle and tubules. Kidneys perfused with CS had some glomerular endothelial injury, but the epithelial cell appeared nearly undisturbed. In the tubular regions, the proximal and distal convoluted portions seemed well preserved but the intertubular capillary endothelium showed discontinuity. Upon transplantation, the ultrastructure was essentially similar. In all 1-hr transplant biopsies there was evidence of erythrocyte aggregation but no indication of fibrin or platelet clotting. From the ultrastructural observations made, it appears that significant endothelial injury did occur in the PPF and CS groups during the course of perfusion whereas little or no change was found in the CPP group.     

Microparticle formation after co-culture of human whole blood and umbilical artery in a novel in vitro model of flow

Cardiovascular disease (CVD) is now the largest killer in western society, and the importance of interactions between vascular endothelium and circulating blood components in disease pathogenesis is well established. Microparticles are a heterogeneous population of <1 μm blood borne particles that arise from blebbing or shedding of cell membranes. The microparticle population includes several classes of apoptotic bodies; however, increased numbers of procoagulant microparticles have been described in plasma from people with CVD. We have previously demonstrated that interactions of monocytes and platelets with isolated inflamed endothelial cells lead to production of pro-coagulant tissue factor bearing microparticles under laminar flow conditions. Here we have investigated microparticle production after perfusion of human whole blood through intact inflamed human umbilical artery. When blood was perfused through umbilical arteries which had been pre-stimulated with tumour necrosis factor (TNFα) for 18 h under flow conditions, there was significantly increased production of microparticles from both platelet and non-platelet sources, in particular from erythrocytes. To determine whether microparticles generated during interactions with inflamed endothelium could induce a pro-inflammatory response in trans, we isolated microparticles by centrifugation after co-culture and incubated with isolated quiescent endothelial cells followed by measurement of reactive oxygen species formation. Microparticles derived from co-culture with inflamed endothelium induced significantly enhanced levels of reactive oxygen species (ROS). These data suggest that presence of an inflamed endothelium causes release of pro-inflammatory microparticles from circulating blood cells, which could contribute to prolonged endothelial activation and subsequent atherosclerotic changes in blood vessels subjected to inflammatory insult.     

Coupling of endothelial injury and repair: an analysis using an in vivo experimental model

The repair of the endothelium after inflammatory injury is essential to maintaining homeostasis. The link between inflammation-induced endothelial damage and repair has not been fully characterized in vivo. We have developed a rat model to evaluate the coupling of lipopolysaccharide (LPS)-induced endothelial injury and repair. Aortic endothelium injury was analyzed by both inmunohistochemistry and flow cytometry to quantify the number of endothelial cells and the percentage of apoptotic endothelial cells. We have also identified the percentage of circulating angiogenic cells capable of repairing the damaged endothelium. Erythropoietin was administered to inhibit LPS-induced endothelial apoptosis. Loss of the normal endothelial structure was observed in the aorta of the animals treated with LPS. Eight hours after LPS administration, the number of endothelial cells decreased by 40%, returning to normal after 24 h. There was a threefold increase in the percentage of circulating angiogenic cells, which did not return to normal levels until 48 h after LPS administration. Circulating angiogenic cell levels did not change when LPS-induced endothelial damage was prevented by erythropoietin. The endothelial injury caused by inflammation activates the mobilization of circulating angiogenic cells, thus completing endothelial repair. Inflammation without endothelial injury does not trigger the mobilization of circulating angiogenic cells.     

Characterisation of the interaction between circulating and in vitro cultivated endothelial progenitor cells and the endothelial barrier

In vitro cultured endothelial progenitor cells (cEPC) are used for intracoronary cell therapy in cardiac regeneration. The aim of this study was to investigate whether cEPC and circulating mononuclear cells (MNC), which include a small number of in vivo circulating EPC, are able to transmigrate through the endothelial barrier into the cardiac tissue. MNC and EPC were isolated from the peripheral blood from healthy male volunteers (n = 13, 25+/-6 years) and stained with a fluorescent marker. The cells were perfused in vitro through organs with endothelial layers of different phenotypes (rat aorta, human umbilical vein, isolated mouse heart). The endothelium and the basal lamina were then stained by immunofluorescence and the cryo-sections analysed using a confocal laser scanning microscope. After perfusion through the rat aorta, an adhesion/integration of MNC was observed at the endothelial layer and the basal lamina beneath endothelial cells. However, no migration of MNC over the endothelial barrier was found. This remained true even when the cell numbers were increased (from 0.5 to 10 million cells/h), when the time of perfusion was prolonged (1.5-4 h) and when the aorta was cultivated for 24 h. In the Langendorff-perfused mouse heart with intact endothelium, no migration of MNC (1 x 10(7)) or cEPC (1 x 10(6)) was observed after 0.5 and 2 h. In conclusion, MNC and cEPC do not possess any capacity to transmigrate the endothelial barrier. In the context of stem cell therapy, these cells may therefore serve as endothelial regenerators but not as cardiomyocyte substitutes.     

Effect of thiol-oxidation of glutathione with diamide on corneal endothelial function, junctional complexes, and microfilaments

Intracellular-reduced glutathione (GSH) was removed by thiol-oxidation with diamide during in vitro perfusion of the corneal endothelium. By 15 min the normal mosaic-like pattern of the endothelial cells was disrupted by serpentine-like lines of cell separation at the cell juntions. After 45 min of perfusion, infividual clusters of cells formed cup-shaped islands. The resultant exposure of Descemet's membrane to the perfusion solution resulted in corneal swelling. Transmission electron microscopy revealed that the endothelial cells separated at the apical junctions and that the microfilaments in the apical cytoplasm of cells formed dense bands, whereas the other subcellular organelles were normal in appearance. The change in cellular shape may be due to loss of cellular adhesion which results in the condensation of the microfilaments or contraction of the microfilaments. The addition of glucose to the perfusate prevented the diamide effect, and the diamide effect could be reversed upon removal and perfusion of a glutathione bicarbonate Ringer's solution. These results suggest that the ratio of reduced to oxidized glutathione in the endothelial cells plays a role in the maintenance of the endothelial cell barrier function.     

Integrin αvβ5 in endothelial cells of rat splenic sinus: an immunohistochemical and ultrastructural study

Localization of integrins β1-8, α1, α2, α3, α5, α6 and αv in sinus endothelial cells of the rat spleen was examined by immunofluorescence microscopy. Labeling for anti-integrin β5 and integrin αv was detected and colocalized in the entire circumference of endothelial cells. Labeling for integrin β5, vinculin and actin filaments demonstrated that they lay close to each other in the basal part of the endothelial cells. Although the other integrin βs, including integrin β1 and integrins α1, α2, α3, α5 and α6 in combination with integrin β1, were localized in leukocytes, slightly large cells, megakaryocytes and/or platelets in the sinus lumen and splenic cords, they were not detected in endothelial cells. Labeling for vitronectin, a component of the extracellular-matrix-binding integrin αvβ5, was strongly stained in the periphery of the wall of sinuses, as was collagen IV and, in addition, was localized in the cytoplasm of endothelial cells. Ultrastructural localization of integrin β5, vitronectin and clathrin was examined by immunogold electron microscopy to elucidate the involvement of integrin αvβ5 in the endocytosis of vitronectin in sinus endothelial cells. Electron microscopy with detergent extraction revealed abundant coated pits and coated vesicles in endothelial cells. Immunogold labeling for vitronectin was present in pits, vesicles and the stacked endoplasmic reticulum. Double-labeling for integrin β5 or integrin αv and clathrin revealed that they were colocalized in some vesicles in close proximity to the apical and lateral plasma membrane of the endothelial cells. The possible functional roles of integrin αvβ5 in endothelial cells of the splenic sinus are discussed.     

Arsenic Exposure Increases Monocyte Adhesion to the Vascular Endothelium,a Pro-Atherogenic Mechanism

Epidemiological studies have shown that arsenic exposure increases atherosclerosis, but the mechanisms underlying this relationship are unknown. Monocytes, macrophages and platelets play an important role in the initiation of atherosclerosis. Circulating monocytes and macrophages bind to the activated vascular endothelium and migrate into the sub-endothelium, where they become lipid-laden foam cells. This process can be facilitated by platelets, which favour monocyte recruitment to the lesion. Thus, we assessed the effects of low-to-moderate arsenic exposure on monocyte adhesion to endothelial cells, platelet activation and platelet-monocyte interactions. We observed that arsenic induces human monocyte adhesion to endothelial cells in vitro. These findings were confirmed ex vivo using a murine organ culture system at concentrations as low as 10 ppb. We found that both cell types need to be exposed to arsenic to maximize monocyte adhesion to the endothelium. This adhesion process is specific to monocyte/endothelium interactions. Hence, no effect of arsenic on platelet activation or platelet/leukocyte interaction was observed. We found that arsenic increases adhesion of mononuclear cells via increased CD29 binding to VCAM-1, an adhesion molecule found on activated endothelial cells. Similar results were observed in vivo, where arsenic-exposed mice exhibit increased VCAM-1 expression on endothelial cells and increased CD29 on circulating monocytes. Interestingly, expression of adhesion molecules and increased binding can be inhibited by antioxidants in vitro and in vivo. Together, these data suggest that arsenic might enhance atherosclerosis by increasing monocyte adhesion to endothelial cells, a process that is inhibited by antioxidants.     

Shape transformation and cytoskeletal reorganization in activated non-mammalian thrombocytes

The nucleated thrombocytes of non-mammalian vertebrates are partially flattened, ovoid cells morphologically distinct from mammalian platelets, and the extent of their functional equivalence is unknown. To test whether they resemble platelets in having similar F-actin-based post-activation stages, rapid fixation/extraction/labeling methods were developed to reveal cytoskeletal organization in dogfish thrombocytes by confocal microscopy. Unactivated cells contained cortical F-actin plus denser F-actin co-localizing with outer marginal band (MB) microtubules. In the post-activation sequence, determined for the first time by continuous observation of individual thrombocytes following thrombin perfusion, cells rounded and blebbed, spread, and eventually flattened extensively. The MB twisted and then became disorganized, with microtubule bundles remaining centrally located and associated with nuclear clefts. In contrast, F-actin occupied blebs and outward-spreading cytoplasm, initially in spiky projections, then predominantly in stress fibers, and inhibitors of F-actin assembly or myosin ATPase blocked shape changes. Thus, the post-activation stages and cytoskeletal events observed in nucleated thrombocytes were found to parallel those of platelets.