Transport pathways for macromolecules in the aortic endothelium. II. The distribution analysis of plasmalemmal vesicles reconstructed by serial sections

Three-dimensional organization of vesicles was examined to elucidate the transendothelial transport properties for macromolecules in rat aortic endothelium using ultrathin serial sections and horseradish peroxidase (HRP) as a tracer molecule. A total number of reconstructing vesicles was 1,298 in nine series electron micrographs, if each vesicular entity was counted as one regardless of composite number of vesicles. The vesicles could be classified into the following six types: HRP-positive luminal, abluminal and intercellular invaginations; HRP-positive channels; HRP-positive and -negative vesicles. The vesicular invaginations and the channels occupied 97.8% and 0.9% of the total vesicles, whereas HRP-positive and -negative free vesicles were found in 0.8% and 0.5%, respectively. The average numerical density of the luminal invagination was 41.1/μm² and approximately equal to that of the abluminal invagination (42.0/μm²), whereas the frequency of the latter was 1.4 times higher than that of the former since the abluminal surface of the endothelium was more irregular to increase a surface area. Each endothelial region varied in the vesicular density and the peripheral region generally showed the higher density, although the transendothelial channels composed of vesicles were not always found in every peripheral region. These results suggest that the shuttle hypothesis is unsuitable to explain “vesicular transport” in the arterial endothelium as well as in the capillary endothelium and that the channels in the peripheral region mainly control transendothelial transport for macromolecules via vesicles. © 1993 Wiley-Liss, Inc.     

Perturbation of the blood-retinal barrier after enzyme perfusion. A cytochemical study

The retina is protected from circulating molecules by a blood-retinal barrier. This is comprised of the impermeable apical-lateral junctions of the retinal pigment epithelium and intraretinal blood vessels lined by endothelia that have impermeable junctions and vesicles that do not transport material from the luminal to abluminal front. This study examined the effect of enzyme digestion upon the restrictive properties of the retinal capillary endothelium. Rats were perfused first with enzymes and then by hemoglobin that was visualized by ultrastructural cytochemical methods. After perfusion of buffer alone or buffers containing neuraminidase or heparinase, the cytochemical reaction product was confined to the capillary lumina and to endothelial cell vesicles facing the luminal front. In contrast, after heparitinase or pronase perfusion, reaction product filled the extravascular spaces. Chains of endothelial cell vesicles and patent transendothelial channels were often encountered. Endothelial cell junctions did not appear to be affected by enzyme treatment. These findings indicate that a cell-surface heparan sulfate proteoglycan (or a nonidentified protein removed by proteolysis) is a key molecule required for the maintenance of the blood-retinal barrier.     

Morphological and ultrastructural changes in the placenta of the diabetic pregnant Egyptian women

Diabetes mellitus (DM) is a chronic metabolic disease in which the body fails to produce enough insulin or increased tissue resistance to insulin. The diabetes may have profound effects on placental development and function. This study was designed to detect the placental changes in pregnancy associated with DM comparing these changes with normal placenta. The study was carried out on sixty full-term placentae; divided into three equal groups; control group (group I): placentae of normal pregnancy, uncontrolled diabetes (group II): placentae from pregnant women whose blood glucose is poorly controlled during pregnancy. Controlled diabetes (group III): includes placentae from diabetic women whose blood glucose is controlled during pregnancy. The placentae from group II tend to be heavier and exhibited immaturity of villi, villous edema, fibrosis, excessive syncytial knots formation and infarctions. In addition to, fibrinoid necrosis, increased thickness of vasculosyncytial membrane, syncytial basement membrane, microvillous abnormalities and vascular endothelial changes were demonstrated. The syncytial multivesicular knots were present in placentae of group II. The nuclei within these syncytial knots display condensed chromatin, either dispersed throughout the nucleus or in the form of dense peripheral clumps with and numerous cytoplasmic vacuoles. The syncytial basement membrane showed focal areas of increase in its thickness and irregularity. Villous cytotrophoblasts showed increased number and activity in the form of numerous secretory granules, abundant dilated RER, larger distorted mitochondria. Villous vessels showed various degrees of abnormalities in the form of endothelial cell enlargement, folding, thickening and protrusion of their luminal surfaces into vascular lumen making it narrower in caliber. In placentae of group III, most of these abnormalities decreased. In most of placentae of group III, the VSM appeared nearly normal in thickness and showed nearly normal composition of one layer of syncytiotrophoblastic cells, one layer of smooth, regular capillary endothelium and the space between them. Mild microvillous abnormalities were noted in few placentae as they appeared short and blunted with mild decrease in their number per micron. The electron picture of syncytial knots appeared nearly normal containing aggregations of small, condensed hyperchromatic nuclei, minimal vacuoles could be seen in the cytoplasm of syncytial knots. Syncytial basement membrane appeared regular and nearly normal in its thickness and composition coming in direct contact with fetal blood capillaries but mild abnormalities were noted in the basement membrane in few placentae as increased its thickness and deposition of fibers or fibrinoid. Regarding cytotrophoblasts in the terminal villi of placentae with controlled diabetes, these cells appeared nearly normal. They were scattered beneath the syncytium and were active containing mitochondria, rough endoplasmic reticulum, free ribosomes and a large nucleus with fine dispersed chromatin. The vascular ultrastructural pattern in terminal villi of placentae of this group showed no significant abnormalities and was normally distributed in the villous tree. The luminal surface of the vascular endothelium appeared regular smooth in the majority of placentae of this group. The endothelial cells appeared connected to each other with tight junctions. It could be concluded that whether if long-term diabetes is controlled or not, placentae of diabetic mother showed a variety of significant histological structural changes seen more frequently than in the placentae of pregnant women without diabetes.     

Plasma membrane-associated vesicles in retinal capillaries of the rat

The structure and function of abluminal vesicles in endothelial cells of rat retinal capillaries was examined using glutaraldehyde—tannic acid fixation and the hemeproteins—horseradish peroxidase, microperoxidase, and lactoperoxidase—as tracers. Numerous vesicles, delimited by a tannic acid—positive membrane, were distributed along the abluminal front. Other vesicles were arranged in clusters and chains or tubule-like structures. Such vesicles were not found in the vicinity of the capillary lumen. When the retina was exposed to hemeproteins, either in vitro or after intravitreal injection, the abluminal vesicles became labeled with tracer reaction product. Apparently “free” vesicles and tubules seen in tangential sections through the basal lamina were also labeled, suggesting that they were in continuity with the plasma membrane in another plane of section. No enzyme reaction product was present in the capillary lumen. Peroxidase-positive multivesicular bodies were observed, suggesting that some protein was endocytosed and directed to lysosomes where it was presumably degraded. The results suggest that abluminal endothelial vesicles represent pits or invaginations of the plasma membrane and, as such, are not involved in the transendothelial transport of protein from the perivascular space to the capillary lumen. Tannic acid treatment revealed a population of similar vesicles associated with the plasma membrane of pericytes. After exposure to hemeproteins, enzyme reaction product was localized in these vesicles and in a few multivesicular bodies. The results suggest that the majority of these vesicles are in continuity with the plasma membrane and are not involved in endocytosis.     

Three-dimensional analysis of vacuoles and surface invaginations of capillary endothelia in the eel rete mirabile

One layer of attenuated endothelia of continuous capillaries provides a partially selective diffusion barrier between the blood and the interstitium. Ultrastructures of membrane specialization without the known physiologic functions have been found in blood vessel endothelia. The vacuolar profiles or vacuole-like, membrane-bound structures, which are larger than plasmalemmal vesicles, have been observed routinely in normal endothelial cytoplasm or in blood vessels challenged by insults in electron microscopic studies. Three-dimensional information from serial sections is required to understand the organization and functions of vacuole-like structures in capillary endothelium. The capillaries in eel retia mirabile were perfused with electron-dense tracers, glutaraldehyde in buffer, and were processed for transmission electron microscopy. Ribbons of serial thin sections without counterstaining were examined under a transmission electron microscope. The vacuolar profiles inside endothelial cytoplasm were investigated with the techniques of serial section analysis and three-dimensional reconstruction from serial sections. The vacuole-like structures inside endothelial cytoplasm either were connected to extracellular (luminal, abluminal) compartments or existed as isolated vacuoles from serial section analysis. In the eight series examined in this study, six of ten vacuole-like structures were classified as isolated vacuoles inside endothelia, and their diameters ranged between 186 nm and 266 nm. Two of ten vacuole-like structures were found to extend to the luminal surface of capillaries as luminal, pocket-like invaginations. One of ten vacuole-like structures was found to be connected to the albuminal compartment, and another one existed as an extracellular compartment surrounded by endothelia. Three-dimensional projection of the vacuolar compartments from serial sections showed that endothelial cytoplasm of sheet shape protruded and folded over adjacent endothelium. Three-dimensional information from serial sections reveals the organization of vacuolar profiles and pocket-like invaginations from the cell surfaces in capillary endothelium. The vacuolar profiles in capillary endothelia in two-dimensional electron photomicrographs may represent the extracellular compartments surrounded by the endothelial finger-like extensions. The results indicate that the luminal and abluminal surfaces of the capillary lumen are not smooth or static, and endothelia may change their shape in three dimensions through cytoplasmic protrusions when the tissue environment changes. Anat. Rec. 252:546–553, 1998. © 1998 Wiley-Liss, Inc.     

Endothelial vesicular system in rapid-frozen muscle capillaries revealed by serial sectioning and deep etching

Endothelial plasmalemmal vesicles were examined in serial sections and in deep-etch replicas of rapid-frozen rat muscle capillary endothelium. Numerous fused vesicles were observed in both preparations. The morphology of the vesicles in rapid-frozen capillaries differed from that in the chemically fixed ones; rapid-frozen vesicles were spherical rather than ovoid, and the necks of caveolae and the connecting portion of fused vesicles were wider than those of chemically fixed ones. In the serial sections, true free vesicles were rarely identified (1.6%). In the deep-etch replicas, some of the cytoplasmic surface of vesicles had a mulberrylike appearance and intracytoplasmic fine fibrils appeared to connect the vesicles either to other vesicles or to the plasmalemma proper. Two transendothelial channels were found among 250 capillary profiles. Almost all endothelial "vesicles" proved to be invaginations of the surface membrane, and chemical fixatives did not seem to induce any substantial membrane fusion. These observations suggest that transendothelial transport of large macromolecules across continuous capillary endothelium is carried out mainly by diffusion through transendothelial channels.     

Caveolar and intercellular channels provide major transport pathways of macromolecules across vascular endothelial cells

Serum macromolecules are transported through the vascular endothelial layer to the interstitium via the caveolae and interendothelial clefts, but the nature of the permeability of these structures is unknown, and the manner of caveola-vesicle transport is controversial. We have developed a method of detecting macromolecular channels using an in situ HRP perfusion into arteries previously perfused with aldehyde and random conventional sectioning for electron microscopy. Using unbiased morphometry, 4.75% of the abluminal caveolae and 15.13% of the intercellular clefts were the tracer-positive in rat aortic endothelium. In rat aortas treated with N-ethylmaleimide, all caveolae and most free vesicles in the cytoplasm except those around the Golgi area were HRP-positive in the endothelial cells; 1.48% of abluminal caveolae were structurally recognized as caveolar channels through the endothelial layer in a plane of single section. The length density of the abluminal caveolae was decreased to about 80% to the physiological control level whereas the larger invaginations were more frequently observed. Moreover 96.17% of the intercellular clefts were HRP-positive. We suggest that a flexible channel-system functions extensively as a macromolecular transport pathway in the arterial endothelium in vivo because the tracer-labeled abluminal caveolae and intercellular clefts should be opened to the luminal surfaces methodologically. We therefore propose that caveolar channels, rather than transcytosis, provide a mechanism of caveola-vesicle transport in the endothelial cells, because free vesicles involved in transcytosis were few in number.     

Electron Microscopic Studies on IgA Nephropathy

We carried out electron microscopic studies on renal tissues from 9 patients with IgA nephropathy. Electron dense deposits were present in the mesangial area in all cases, subendothelial deposits in 4, and subepithelial deposits in only one. In basement membrane, segmental swelling and rarefaction of basement membrane substance were observed. In some cases the degenerated basement membrane substance protruded through the dilated endothelial fenestration into capillary lumina. Focal splitting, attenuation, mouse eaten appearance, and herniation of basement membrane were seen in a high incidence. Mesangial cells possessed well developed rough endoplasmic reticulums and polysomes. In the peripheral areas of mesangial cell cytoplasm, there was accumulation of electron dense substance and this was occasionally continuously present in the mesangial matrix. There was segmental swelling of endothelial cell cytoplasm, resulting in loss of fenestration. Epithelial cells had well developed rough endoplasmic reticulums and polysomes. Segmental foot process fusion was seen, and these processes, regardless of fusion, became electron denser in the area close to the basement membrane. Multivesiculated bodies were present in all cases in the epithelial cells and in 7 cases in the endothelial cells. Spherical microparticles were present in 3 cases in the urinary space or between the basement membrane and the epithelial cells.     

Tubular profiles do not form transendothelial channels through the blood-brain barrier

Summary The contribution of tubular profiles within the mammalian cerebral endothelium to the formation of transcellular channels was analysed following exposure of the endothelium to native horseradish peroxidase (HRP) dissolved in saline or dimethyl sulphoxide (DMSO) administered intravenously in mice. Within 5–15 min, but not at 30 min to 2h postinjection, peroxidase-positive extravasations were evident within the parenchyma of the forebrain and brainstem of mice exposed and not exposed to DMSO. The extravasations may be associated with the rupture of interendothelial tight junctions at the level of arterioles as a consequence of the perfusion-fixation process. Ultrastructural inspection of endothelia within and away from areas of peroxidase extravasation revealed the following intraendothelial, peroxidase-positive organelles: presumptive endocytic vesicles, endosomes (a prelysosomal compartment), multivesicular and dense bodies, and tubular profiles. Statistical analysis of the concentration of HRP-labelled presumptive endocytic vesicles, which may coalesce to form tubules, within endothelia from mice injected intravenously with HRP-DMSO compared to mice receiving HRP-saline revealed no significant difference. HRP-positive tubular profiles were blunt-ended, variable in length and width, and appeared free in the cytoplasm or in continuity with dense bodies. Labelled tubules free in the cytoplasm were positioned parallel to the luminal and abluminal plasma membranes and were less frequently oblique or perpendicular to these membranes. Tubular profiles analysed in serial thin sections or with a goniometer tilt stage did not establish membrane continuities with the luminal and abluminal plasma membranes. Peroxidase-positive tubular profiles were similar morphologically to those exhibiting acid hydrolase activity but did not share morphological and enzyme cytochemical similarities with the endoplasmic reticulum that stained for glucose-6-phosphatase (G6Pase) activity. G6Pase-positive profiles of endoplasmic reticulum were not observed to contribute to a transendothelial canalicular network. Our results suggest that: (i) peroxidase-labelled tubules, acid hydrolase-positive tubules, and G6Pase-positive endoplasmic reticulum do not form transcellular channels through the cerebral endothelium; (ii) tubular profiles labelled with blood-borne HRP in the cerebral endothelium are associated with the eridosome apparatus and/or the lysosomal system of organelles; and (iii) DMSO does not appear to alter the permeability of the blood-brain barrier to blood-borne protein.     

Role of intercellular junctions in the passage of horseradish peroxidase across aortic endothelium.

BACKGROUND: The manner in which molecules are transported across the arterial endothelial layer has been a subject open to much interpretation and controversy. Further elucidation and clarification of these mechanisms are of primary interest. EXPERIMENTAL DESIGN: To investigate the ultrastructural features of arterial endothelial junctions and to evaluate their functional roles as a transendothelial pathway for macromolecular transport, experiments were performed on the thoracic aortae of adult male Sprague-Dawley rats by using the ultrathin serial sectioning technique and horseradish peroxidase (HRP). The aorta was perfusion-fixed with or without prior intravenous injection of HRP. RESULTS: The intercellular clefts exhibited a great deal of variety in shape, being linear, winding, interdigitated, irregular and/or dumbbell-shaped in appearance. Besides the typical 20-nm width encountered at the uniform region of intercellular clefts, local widenings (up to several hundred nm) were quite common. The arterial endothelial junctions were highly organized. Junctional elements, including tight junctions and gap junctions, were frequently present in the same intercellular cleft, even on the same plane of sectioning. Sometimes, gap junctions were found without tight junctions, but the intercellular clefts were rarely obliterated by tight junctions alone. Some intercellular clefts were not obliterated by either gap or tight junctions, and HRP was found to reach the subendothelial space by passing through these junctionless clefts. Densitometric determination of the HRP concentration profile in such junctionless clefts showed a decreasing gradient from the luminal to the abluminal front. The serial sections provided evidence that the apparently free vesicles were actually plasmalemmal membrane invaginations open to the luminal or abluminal front in the arterial endothelium. CONCLUSIONS: The present study showed that the junctionless normal endothelial clefts, in addition to the transiently open junctions surrounding mitotic cells, might provide a significant pathway in the transendothelial transport of macromolecules with the size of HRP.     

Functional maturation of the capillary wall in the fetal and neonatal rat heart: Permeability characteristics of developing myocardial capillaries

The development of the functional components of the myocardial capillary wall was characterized by time-course studies of transendothelial transport of intravascularly injected probes of graded size from 16 days of gestation in the fetal rat to seven days postpartum. Despite the morphological changes occurring in the developing endothelial cells, the interaction of the probes was similar throughout the developmental period studied. The carbon particles were retained within the capillary lumina without any association with interendothelial junctions or with plasma-lemmal vesicles. Carbon also was associated with coated vesicles. In contrast to carbon, ferritin was localized sequentially, over 60 sec of circulation, in plasmalemmal vesicles on the lumenal surface, in the cytoplasm, and on the ablumenal surface of the endothelial cells as well as in the interstitial space. Ferritin was located also in coated pits and vesicles and, after 90 sec of circulation, in multivesicular bodies. Within 30 sec of circulation, reaction product of myoglobin was located in plasmalemmal vesicles, coated vesicles, and transendothelial cell channels. Also within 30 sec, myoglobin partially filled the interendothelial space from the capillary lumina to the level of the tight junction. At all developmental ages studied, the interendothelial cell junctions appeared structurally tight and were impermeable to all of the probes. Once ferritin or myoglobin had reached the ablumenal space, the basal lamina did not appear to restrain the passage of the probes. Plasmalemmal vesicles are the capillary structures which transendothelially transport ferritin and myo-globin in developing myocardial capillaries.     

Localization of norepinephrine and serotonin transporter in mouse brain capillary endothelial cells

Monoamines function as a vasoactive modulator in the central nervous system (CNS) and are believed to regulate blood-brain barrier (BBB) function. Although monoamine transport is an essential process for regulating the extracellular monoamine concentration, the transport systems for monoamines at the BBB are poorly understood. mRNA expression of norepinephrine transporter (NET) and serotonin transporter (SERT) has been detected in a conditionally immortalized mouse brain capillary endothelial cell line (TM-BBB4) used as an in vitro model of the BBB, whereas no dopamine transporter (DAT) was detected. Western blot analysis showed the expression of NET and SERT protein in the membrane fraction of mouse brain capillaries and TM-BBB4 cells. Immunohistochemical analysis revealed that NET and SERT are localized at the brain capillaries in the mouse cerebral cortex, and suggests that NET is localized at the abluminal side of brain capillary endothelial cells, and SERT is localized at the luminal and abluminal sides. NET and SERT expressed at the BBB may be involved in the inactivation of monoamines released from neurons around the BBB.     

Influence of angiogenesis inhibitors on endothelial cell morphology in vitro

Human umbilical vein endothelial cells (HUVEC) propagated in co-culture with fibroblasts form capillary-like networks of tubes. Here we characterize the morphology and ultrastructure of HUVEC in such co-cultures and investigate the influence of different angiogenesis inhibitors on endothelial cell morphology. Addition of angiogenesis inhibitors to the co-culture disrupted endothelial network formation and influenced endothelial cell morphology in two distinct ways. Instead of characteristic capillary-like networks, the endothelial cell morphology appeared as either short cords or compact cell clusters of variable size. Electron microscopy (EM) showed that in co-culture untreated HUVEC formed capillary-like tubes with lumina and retained important ultrastructural and physiological properties of endothelial cells in functional vessels as they contained both Weibel-Palade bodies and transport vesicles. Immuno-EM showed that the endothelial cell marker CD 31 stained endothelial membranes at cell-cell contacts, and at the luminal and abluminal side of the capillary-like tubes, although most abundantly at the luminal membranes. No ultrastructural signs of apoptosis were seen in HUVEC in inhibitor-treated co-cultures. Our results demonstrate that treatment with levamisole or anti-VEGF inhibits endothelial cell differentiation into tubes or instead induces formation of compact endothelial cell clusters. Treatment with platelet factor 4, suramin and TNP-470 results in formation of short endothelial cell cords. We discuss the implications of these findings.     

Production of two novel monoclonal antibodies that distinguish mouse lymphatic and blood vascular endothelial cells

We produced two novel rat monoclonal antibodies (LA102 and LA5) to identify mouse lymphatic vessels and blood vessels, respectively. We characterized the two antibodies as to the morphological and functional specificities of endothelial cells of both types of vessels. The antibodies were produced by a rapid differential immunization of DA rats with collagenase- and neuraminidase-treated mouse lymphangioma tissues. LA102 specifically reacted with mouse lymphatic vessels except the thoracic duct and the marginal sinus of lymph nodes, but not with any blood vessels. In contrast, LA5 reacted with most mouse blood vessels with a few exceptions, but not with lymphatics. LA102 recognized a protein of 25–27 kDa, whereas LA5 recognized a molecule of 12–13 kDa. Neither antibody recognized any currently identified lymphatic or vascular endothelial cell antigens. Immunoelectron microscopy revealed that the antigens recognized by LA102 and LA5 were localized on both luminal and abluminal endothelial cell membranes of each vessel type. Interestingly, LA102 immunoreactivity was strongly expressed on pinocytic or transport vesicle membrane in the cytoplasm of lymphatic endothelium. Besides endothelial cells, both antibodies also recognized some types of lymphoid cells. Since, the LA102 antigen molecule is expressed on some lymphoid cells, it may play important roles in the migration of lymphoid cells and in some transport mechanisms through lymphatic endothelial cells.     

Migration of the fungal pathogen Candida albicans across endothelial monolayers.

Migration of the fungal pathogen Candida albicans across the endothelial cell layer is considered a prerequisite for the invasion of multiple organs occurring in systemic candidiasis. We developed an experimental system in which C. albicans migrates from a luminal compartment across a monolayer of bovine aortic endothelial cells on a porous filter support to an abluminal compartment. In this system, a C. albicans wild-type strain (ATCC 10261) traverses the endothelial monolayer in a time-, glucose-, and cell concentration-dependent manner. A mutant derivative unable to grow and form hyphae (SGY-243) migrates at a reduced rate. Concomitant to transendothelial migration, the permeability of the endothelial monolayer for dextran diffusion markers is significantly increased. This increase in transendothelial exchange occurs before fungal cells are detectable in the abluminal compartment and is time, glucose, and cell concentration dependent. A mutant strain (hOG301) unable to interact with endothelial cells does not alter endothelial permeability. Thus, transendothelial migration of C. albicans is able to damage the barrier function of an endothelial monolayer. Our experimental system, which reflects key stages of transendothelial migration of C. albicans including adherence and passage across endothelial cells and the extracellular matrix, may be a useful model for comparisons of transendothelial migration characteristics of Candida strains.     

Regulation of amino acid and glucose transporters in endothelial and smooth muscle cells

While transport processes for amino acids and glucose have long been known to be expressed in the luminal and abluminal membranes of the endothelium comprising the blood-brain and blood-retinal barriers, it is only within the last decades that endothelial and smooth muscle cells derived from peripheral vascular beds have been recognized to rapidly transport and metabolize these nutrients. This review focuses principally on the mechanisms regulating amino acid and glucose transporters in vascular endothelial cells, although we also summarize recent advances in the understanding of the mechanisms controlling membrane transport activity and expression in vascular smooth muscle cells. We compare the specificity, ionic dependence, and kinetic properties of amino acid and glucose transport systems identified in endothelial cells derived from cerebral, retinal, and peripheral vascular beds and review the regulation of transport by vasoactive agonists, nitric oxide (NO), substrate deprivation, hypoxia, hyperglycemia, diabetes, insulin, steroid hormones, and development. In view of the importance of NO as a modulator of vascular tone under basal conditions and in disease and chronic inflammation, we critically review the evidence that transport of L-arginine and glucose in endothelial and smooth muscle cells is modulated by bacterial endotoxin, proinflammatory cytokines, and atherogenic lipids. The recent colocalization of the cationic amino acid transporter CAT-1 (system y(+)), nitric oxide synthase (eNOS), and caveolin-1 in endothelial plasmalemmal caveolae provides a novel mechanism for the regulation of NO production by L-arginine delivery and circulating hormones such insulin and 17beta-estradiol.     

Electron microscopy of the red pulp of human spleen

Terminating arterial vessels, the structure of sinuses and cords, and the passage of cells through the sinus wall in the red pulp of human spleen were studied. All terminating arterial capillaries arterial capillaries observed opened into cords. The distance between terminating arterial capillaries and sinuses varied. Macrophages were commonly present at arterial terminations. Arterial capillary endothelium contained filaments about 80 Å in diameter. Blood cells were frequently present in the capillary lumen or in passage through the capillary wall into cords. Endothelial cells of sinuses contained three distinctive structures: loosely organized cytoplasmic filaments, tightly organized finer filaments, and micropinocytotic vesicles. Many micropinocytotic vesicles about 0.1 μ in diameter were present just beneath the plasma membrane of the lateral and luminal sides of sinus endothelial cells and a few at the basal aspect. Loosely organized filaments about 80 Å in diameter ran parallel to the longitudinal axis of the sinus endothelium. The finer filaments about 30–50 Å in diameter were tightly organized as filamentous bands and present basally. The filaments of the bands appeared inserted upon the plasma membrane. They were also present in the cordal reticular cells and terminating arterial capillaries. Free cells were frequently present in passage through the slits of the sinus wall. There were no preformed or fixed apertures in the sinus wall. The basement membrane and reticular fibers were completely covered by the endothelial cells and/or cordal reticular cells. It is likely that those slits between endothelial cells in the sinus wall not covered by the basement membrane are potential passageways for cells moving from the cords into the sinus. The larger cytoplasmic filaments are likely contractile. The filamentous bands appear to maintain cell shape, stabilize the wall in relation to the basement membrane, and are probably operative in the control of cellular passage through the slits of sinus wall.     

气管的器官内淋巴管

本文应用淋巴管间接注射法以及光镜和电镜观察的方法,对家兔气管的器官内淋巴管进行了研究。在气管粘膜层仅见到毛细淋巴管,彼此吻合成网。气管与喉的粘膜层毛细淋巴管存在吻合,但数量较少。在气管粘膜下层、肌层及外膜层则见到毛细淋巴管和淋巴管。气管毛细淋巴管的超微结构可见,管壁厚薄不均,内皮的多数细胞核向管腔内突出,基膜不完整,无孔窗,无周细胞,壁外有大量纤维束伴行。内皮间连接较复杂,归纳可分为端端连接、重叠连接和嵌合连接。内皮间连接处有粘着装置(如粘着带、粘着斑或桥粒),但较薄弱,有的连接呈开放状态(>30nm)。毛细淋巴管内皮的胞浆内有大量囊泡,其分布无一定规律,有的囊泡与内皮细胞质膜融合或呈开放状态,形成质膜内陷。囊泡形态大小不等,有的体积较大且内部充满颗粒状不均匀物质,有的囊泡外包有电子密度较高的外衣,有些则不明显。     

Subcellular localization of transporters along the rat blood-brain barrier and blood-cerebral-spinal fluid barrier by in vivo biotinylation

Nutrient transporters and ABC efflux pumps at the blood-brain barrier are major determinants of drug penetration into the brain. Immunohistochemical analysis of transporter subcellular localization is challenging due to the close apposition of the luminal and abluminal microvessel plasma membranes. We employed in vivo perfusion of biotinylation reagent through rat brain microvessels to domain-specifically label proteins exposed on the microvessel luminal surface. Using this approach, we analyzed the luminal/abluminal localization of a number of blood-brain barrier transporters identified by quantitative PCR profiling as being highly expressed and enriched in rat brain endothelial cells compared with whole brain. We also examined the apical/basal-lateral distribution of transporters in the choroid plexus, a secondary site for transport of nutrients between the blood and CNS. We detected P-glycoprotein (Pgp) (Abcb1), ATP-binding cassette (Abc) g2, multidrug resistance protein (Mrp) 4 (Abcc4), glucose transporter 1 (Glut1) (Slc2a1), Lat1 (Slc7a5), and monocarboxylate transporter-1 (Mct1) (Slc16a1) on the luminal surface of rat cerebral microvessels by both immunofluorescence staining and Western blotting of in vivo biotinylated proteins. Mrp1 (Abcc1) appeared primarily abluminal by immunofluorescence staining, and was barely detectable in the biotinylated protein fraction. Organic anion transporter (Oat) 3 (Slc22a8), organic anion transporter polypeptide (Oatp) 2b1 (Slco2b1, Oatpb), and Mrp5 (Abcc5) were not detected on the luminal surface using either method, while Oatp1a4 (Slco1a4, Oatp2) appeared to partially localize to the microvessel lumen by immunofluorescence staining, but was not detected in the biotinylated protein fraction by Western blotting. Lat1, Mrp1 and Mrp4 were detected on the basal-lateral surface of lateral ventricle choroid plexus epithelial cells. Mrp5, Oct3 and Oatp2b1 (Oatpb) were detected in the ependymal cells lining the ventricle. We did not detect Pgp expression in choroid plexus by immunofluorescence staining. In vivo biotinylation provides a method for domain-specific labeling of luminal surface proteins within the capillaries of the blood-brain barrier, allowing for biochemical analysis of protein localization and facilitating optical discrimination of the luminal and abluminal endothelial surfaces.     

The anionic matrix at the rat glomerular endothelial surface

The anionic macromolecules at the glomerular endothelial cell surface are visualized only when stained with cationic stains. We investigated the arrangement and composition of this anionic matrix at the luminal surface. Rat kidneys were perfused with anionic ferritin (pI 4.5), ferritin (pI 7.4), or cationized ferritin (CF, pI 8.3). Anionic ferritin (pI 4.5) did not bind to the capillary wall, ferritin (pI 7.4) bound discontinuously only to the laminae rarae of the basement membrane, but cationized ferritin (CF, pI 8.3) bound as a thick continuous layer to the cell plasmalemma and bound to the anionic matrix in the fenestral spaces. These observations show that an anionic matrix lines the entire capillary lumen surface, fills the fenestrae, and is interposed between the blood and the basement membrane at the fenestrae. The anionic constituents at the capillary luminal surface were identified by in vivo digestion with specific enzymes. Absence of CF binding following digestion with specific enzymes was taken to indicate the presence of the particular glycoprotein known to be susceptible to the enzyme used. Neuraminidase digestion revealed that anionic sites over the surface plasmalemma are mainly from sialoproteins. In contrast, the matrix in fenestral channels contains heparan sulfate, hyaluronic acid, and sialoproteins. Papain digestion showed no glycolipids at the luminal surface. The functions of this continuous anionic layer located at the luminal surface of glomerular capillaries have not yet been established.