Identification of albumin-binding proteins in capillary endothelial cells

Isolated fat tissue microvessels and lung, whose capillary endothelia express in situ specific binding sites for albumin, were homogenized and subjected to SDS-gel electrophoresis and electroblotting. The nitrocellulose strips were incubated with either albumin-gold (Alb-Au) and directly visualized, or with [125I]albumin (monomeric or polymeric) and autoradiographed. The extracts of both microvascular endothelium and the lung express albumin-binding proteins (ABPs) represented by two pairs of polypeptides with major components of molecular mass 31 and 18 kD. The ABP peptides have pIs 8.05 to 8.75. Rabbit aortic endothelium, used as control, does not express detectable amounts of ABPs. The ABPs subjected to electrophoresis bind specifically and with high affinity (Kd = approximately 60 X 10(-9)M) both monomeric and polymeric albumin: the binding is saturable at approximately 80 nM concentration and 50% inhibition is reached at 5.5 micrograms/ml albumin concentration. Sulfhydryl-reducing agents beta-mercaptoethanol and dithiothreitol do not markedly affect the ABPs electrophoretic mobility and binding properties. As indicated by cell surface iodination of isolated capillary endothelium followed by electroblotting, autoradiography, and incubation with Alb-Au, the bands specifically stained by this ligand are also labeled with radioiodine.     

Penetration of lipoproteins through a capillary wall and their effects on the cardiomyocyte ultrastructure during in vitro heart perfusion

The colloidal gold-labeled lipoprotein (LP) distribution in the myocardium after the 30 min perfusion of isolated working rat heart was studied by electron microscopy. LP of physiological concentrations are shown to be able to interact with the capillary wall and they can be incorporated by endotheliocytes. The velocity and transportation mechanisms of different classes of LP differ. Very low density LP are the most intensively taken up, low density LP enter into interstitium more rapidly than others, high density LP do not leave the capillary wall at all. The passages of labeled LP through endotheliocytes by the receptor-mediated as well as the non-receptor manners are revealed. The transportation through the widened intercellular junctions may be supposed for low density LP. For the fist time LP addendum into the perfusion medium was shown to provoke the activation of interstitial macrophages. During the perfusion duration they take inside and accumulate labeled very low density LP and low density LP in their lysosomes. The internalization may be performed by the specific endocytosis or by the simple phagocytosis. The qualitative and morphometrical analyses show that LP preserve the capillary and cardiomyocyte ultrastructure from perfusion injuries. One may suppose that there are interrelations between the capillary endothelium, the interstitial macrophages and the parenchymal cells in myocardium for realization of plasma LP effects.     

Endocardial endothelium in the rat: junctional organization and permeability

Selective permeability of endocardial endothelium has been suggested as a mechanism underlying the modulation of the performance of subjacent myocardium. In this study, we characterized the organization and permeability of junctional complexes in ventricular endocardial endothelium in rat heart. The length of intercellular clefts viewed en face per unit endothelial cell surface area was lower, and intercellular clefts were deeper in endocardial endothelium than in myocardial vascular endothelium, whereas tight junctions had a similar structure in both endothelia. On this basis, endocardia endothelium. might be less permeable than capillary endothelium. However, confocal scanning laser microscopy showed that intravenously injected dextran 10000 coupled to Lucifer Yellow penetrated first the endocardial endothelium and later the myocardial capillary endothelium. Penetration of dextran 10000 in myocardium occurred earlier through subepicardial capillary endothelium than through subendocardial capillary endothelium. Penetration of tracer might thus be influenced by hydrostatic pressure. Dextran of MW 40000 did not diffuse through either endocardial endothelium or capilary endothelium. The ultrastructure of endocardial endothelium may constitute an adaptation to limit diffusion driven by high hydrostatic pressure in the heart. Differences in paracellular diffusion of dextran 10000 between endocardial endothelium and myocardial vessels, may result from differing permeability properties of the endocardium and underlying myocardium.     

Specific binding sites for albumin restricted to plasmalemmal vesicles of continuous capillary endothelium: receptor-mediated transcytosis

The interaction of homologous and heterologous albumin-gold complex (Alb-Au) with capillary endothelium was investigated in the mouse lung, heart, and diaphragm. Perfusion of the tracer in situ for from 3 to 35 min was followed by washing with phosphate-buffered saline, fixation by perfusion, and processing for electron microscopy. From the earliest time examined, one and sometimes two rows of densely packed particles bound to some restricted plasma membrane microdomains that appeared as uncoated pits, and to plasmalemmal vesicles open on the luminal front. Morphometric analysis, using various albumin-gold concentrations, showed that the binding is saturable at a very low concentration of the ligand and short exposure. After 5 min, tracer-carrying vesicles appeared on the abluminal front, discharging their content into the subendothelial space. As a function of tracer concentration 1-10% of plasmalemmal vesicles contained Alb-Au particles in fluid phase; from 5 min on, multivesicular bodies were labeled by the tracer. Plasma membrane, coated pits, and coated vesicles were not significantly marked at any time interval. Heparin or high ionic strength did not displace the bound Alb-Au from vesicle membrane. No binding was obtained when Alb-Au was competed in situ with albumin or was injected in vivo. Gold complexes with fibrinogen, fibronectin, glucose oxidase, or polyethyleneglycol did not give a labeling comparable to that of albumin. These results suggest that on the capillary endothelia examined, the Alb-Au is adsorbed on specific binding sites restricted to uncoated pits and plasmalemmal vesicles. The tracer is transported in transcytotic vesicles across endothelium by receptor-mediated transcytosis, and to a lesser extent is taken up by pinocytotic vesicles. The existence of albumin receptors on these continuous capillary endothelia may provide a specific mechanism for the transport of albumin and other molecules carried by this protein.     

Quantitative immunocytochemical studies of endogenous albumin in rat aortic endothelial and mesothelial cells

Endogenous albumin was revealed over cellular structures of rat ascendent aorta endothelia and mesothelium, with high resolution and specificity, by applying the protein A-gold immunocytochemical approach. This approach allows albumin distribution to be studied under steady-state conditions. The cellular layers evaluated were the aortic endothelium, the capillary endothelium (vasa vasorum), and the mesothelium externally lining the aorta at this level. Gold particles, revealing albumin antigenic sites, were preferentially located over plasmalemmal vesicles and intercellular clefts of endothelial and mesothelial cells, though with different labeling intensities. The interstitial space was also labeled. Morphometrical evaluation of plasmalemmal vesicles demonstrated a higher surface density for these structures in capillary endothelial cells (12%) compared with those in aortic endothelial (5%) and mesothelial cells (2%). Quantitation of gold labeling intensities over these structures revealed a higher labeling over plasmalemmal vesicles of capillary endothelium than over those of aortic endothelium and mesothelium. This result, together with the higher surface density of plasmalemmal vesicles found in capillary endothelium, suggest an important role of these structures in the transendothelial passage of endogenous albumin, particularly for capillary endothelium. On the other hand, labeling densities over mesothelial clefts were found to be higher than those of capillary and aortic endothelia. Results from this study concur with the proposal of a differential passage of albumin according to the cell lining considered, and suggest to a role for mesothelial intercellular clefts in contributing to the presence of albumin in interstitial spaces.     

Transendothelial transport of macromolecules: the concept of tissue-blood barriers.

In addition to its many functions in biosynthesis, growth, coagulation and rheology, vascular endothelium is anatomically interposed between the vascular space and the tissue fluid. Recent evidence indicates that it mediates cellular and molecular exchange between these compartments. The exchange can occur through differentiated microdomains of endothelium such as fenestrae. These areas are differentiated with regard to surface charge, protein distribution within the lipid bilayer, membrane fluidity and other features. The exchange is also affected by certain characteristics of the molecule to be transported: molecular size, charge, shape and its carbohydrate content. Proportionately, the largest volume of exchange occurs across the endothelial cytoplasm by vesicular transport systems. Two systems are particularly in evidence; (a) receptor-mediated transcytosis which is specific, and (b) fluid-phase endocytosis. The molecule may become modified in transit and the modification may be of essence in determining its target point and its subsequent metabolism. While most of these modifications involve the carbohydrate moiety of the glycoproteins, glycosylation of non-glycoproteins such as albumin, may also be of physiological significance in transendothelial transport. By virtue of its transport potential, albumin can thus affect the transport of other substances. Recent advances in the molecular transport function of endothelium have been reviewed in the context of its physiological and clinical significance. The basis for the concept of a generalized tissue-blood barrier has been offered.     

Estrogen therapy induces collateral and microvascular remodeling

Estrogen increases proliferation and migration of cultured endothelial cells and perfusion of ischemic hindlimbs of rabbits. We tested the hypothesis that estrogen is angiogenic and arteriogenic in the heart during progressive coronary occlusion. Ovariectomized (OVX) and 17beta-estradiol (1 mg.kg(-1).wk(-1) im)-treated OVX (OVX-ES) female New Zealand White rabbits were instrumented with an ameroid occluder on a proximal coronary artery. Four weeks after implantation of an ameroid occluder, we measured myocardial perfusion with microspheres at rest and during adenosine-induced maximal vasodilation. The heart was fixed by perfusion at physiological pressure, and capillary angiogenesis and remodeling were assessed by image analysis of tissue sections in collateral-dependent myocardium. Coronary conductance was higher at rest and during maximal vasodilation in collateral-dependent myocardium of OVX-ES than OVX rabbits. Estrogen treatment increased the wall-to-lumen ratio of collateral vessels while it decreased the wall-to-lumen ratio of noncollateral arteries in normal regions. In normal and collateral-dependent myocardium, mean capillary diameter and capillary volume density were greater in OVX-ES rabbits. However, estrogen had no effect on capillary length density in either region of the myocardium. These data suggest that estrogen induces remodeling of the collateral vasculature and may stimulate growth of the resistance vessels, thereby providing protection during development of a gradual coronary occlusion.     

Fatty acids binding to albumin increases its uptake and transcytosis by the lung capillary endothelium

To determine whether uptake and transcytosis of albumin (A) in continuous capillary endothelia are modified when this protein carries fatty acids, the transport of albumin-oleic acid and albumin-palmitic acid complexes was compared with that of defatted albumin. The probes, either radioiodinated or tagged with 5-nm gold particles (Au), or both, were perfused in situ or injected in vivo; after 3 or 30 min lung fragments were radioassayed or examined by electron microscopy. Both in situ and in vivo, the uptake of fatty acid-carrying albumin (A-FA) was consistently 2 to 3 times higher than that of defatted A. Electron microscopy revealed that A-FA complexes tagged with gold were taken up and transported across the endothelium by plasmalemmal vesicles. Morphometric analysis showed that as compared with A-Au, at 3 min the density of (A-FA)Au bound to plasmalemmal vesicles was 2 to 3 times higher, and the extent of transcytosis was increased. Uptake of the iodinated albumin was more effectively competed by A-FA complexes than by defatted A, suggesting a higher affinity of the former for the albumin binding sites of the endothelium. The results indicate that when carrying fatty acids, albumin is taken up specifically and with high affinity by the capillary endothelium, a process that may play a role in the transport of fatty acids from the plasma to the cells where they are metabolized.     

Early recognition of a discordant xenogeneic organ by human circulating lymphocytes.

Cell-mediated immune mechanisms underlying discordant xenograft rejection are poorly characterized. In our study, using a human to rat xenogeneic ex vivo model, we show that a fraction of human lymphocytes, when perfused through the coronary system of a rat heart, rapidly and specifically adheres to the vascular endothelium and infiltrates the myocardium. Lymphocyte phenotypic analysis before and after perfusion, as well as the use of purified cell subpopulations, demonstrate preferential adhesion of CD3- CD16+ NK cells. NK cell adhesion occurs via xenoreactive antibody-dependent and -independent pathways, because the selective removal of human IgG from the perfusion buffer markedly reduces but does not completely abrogate NK cell sequestration. However, T lymphocytes are retained in the xenoorgan via an antibody-independent pathway, as assessed by the lack of influence of IgG removal. Leukocyte integrins appear to play a crucial role in mediating adhesion of both lymphocyte subsets, because the pretreatment of lymphocytes with anti-CD11a, anti-CD11b, and anti-CD18 antibodies markedly reduces their retention into the xenogeneic organ. Retained human lymphocytes mediate rapid and direct damage of the xenoorgan, as demonstrated by histologic and functional alterations of the endothelium, impaired vascular resistance and in vitro lysis of rat endothelial cells by human NK cells. Taken together, these findings suggest a role for cell-mediated mechanisms in the rapid recognition and rejection of vascularized xenografts.     

The mechanism of the elimination of dead cells in the myocardium of the fetal rat]

At investigation of the intact and damaged myocardium of the rat fetuses (age 17-21 days) several ways of elimination of the perished cells have been revealed: a) exfoliation of the endocardial perished cells into the ventricular cavity; b) phagocytosis by phagocytes of the fetus; c) bordering of the perished cells by endotheliocytes with a subsequent joining of the endothelium to the blood stream. When the fetal myocardium is damaged, elimination of the perished cells is not ensured, nevertheless, during physiological death of the myocardial cells this method is probably effective. The restrictive function of the endothelium plays an essential role in morphogenesis of the heart and is ensured by certain changes in composition of the intercellular substance.     

Light and electron microscopic studies of the murine heart after repeated administrations of ciguatoxin or ciguatoxin-4c.

After repeated ip and oral administrations of ciguatoxin (CTX) and ciguatoxin-4c (CTX-4c), one of the derivatives of CTX, to male ICR mice at a dose of 0.1 microgram/kg for 15 days, resulted in marked swelling of cardiac cells and endothelial lining cells of blood capillaries in the heart was observed. Single doses caused no discernible pathological changes. Damage to the capillaries was followed by prominent effusion of serum and erythrocytes into the interstitial spaces of the myocardium occurred. Swelling of the endothelial lining cells of capillaries caused narrowing of the lumen and accumulation of blood platelets in capillaries, which resulted in multiple single cell necroses of cardiac muscle cells. Within 1 month after the treatments of these phycotoxins, myocytes and capillaries appeared to be normal. Effusion in the interstitial spaces resulted in formation of bundles of dense collagen, which persisted for 14 months. Diffuse interstitial fibrosis was prominent in septum and ventricles, accompanied by bilateral ventricular hypertrophy. A single dose of 0.7 micrograms/kg ip resulted in severe acute heart injuries, followed by diffuse myocardial fibrosis.     

Immunocytochemical localization of the functional fraction of lipoprotein lipase in the perfused heart

The functional (heparin-releasable) fraction of myocardial lipoprotein lipase (LPL) has been located at the lumen surface of capillary endothelium by means of an indirect immunocytochemical perfusion method for electron microscopy. The primary step immunoreactant was an IgG fraction of goat antiserum directed against LPL from rat heart. The second step antibody, conjugated with horseradish peroxidase, was rabbit IgG directed against goat IgG. Peroxidase reaction product, when present, appeared at the surface an in invaginations of the lumenal plasma membrane of capillary endothelium and also on chylomicrons adherent to that membrane. The highest coverage by such product occurred when the highest heparin-releasable heart LPL activity was attained after fat-feeding of rats. Coverage was low when a low level of heparin-releasable heart LPL activity was induced by carbohydrate-feeding. Coverage was very low in the perfused hearts after heparin-release of functional LPL activity. The positive association between these immunocytochemical results and actual levels of functional LPL activities indicates that functional LPL in the isolated rat heart is at the lumen surface of capillary endothelium.     

Histochemical method for simultaneous fiber typing and demonstration of capillaries in skeletal muscle

Since capillary density of skeletal muscle depends on fiber type distribution, fiber typing should accompany measurement of capillary density. To obviate the need for multiple sectioning, we suggest NADH tetrazolium reductase enzyme histochemistry for fiber typing followed (on the same slide) by lectin histochemistry to demonstrate the binding of Ulex europaeus agglutinin, a sensitive marker for endothelium. The method is quick, highly reproducible and gives density estimates comparable to earlier, more tedious methods.     

Perfusion studies of steady flow in poroelastic myocardium tissue

The behaviour of the heart has always elicited interest and particularly the study of its myocardium, as 5–10% of the blood pumped by the heart is passed through the coronary arteries to the myocardium itself. An in-depth investigation of the myocardium behaviour is useful. The present work aims to investigate how myocardium perfusion is influenced by myocardial stress and diseased states, and in general by LV pumping abnormalities. LV myocardial perfusion can then serve as a possible index of the capacity of the LV to respond to its work demand, and thus of the risk of heart failure. The poroelastic analysis of the myocardium based on finite element method (FEM) for regional perfusion through a rectangular element with various physiological ranges of loading conditions was studied.     

Histochemical method for simultaneous fiber typing and demonstration of capillaries in skeletal muscle

Summary Since capillary density of skeletal muscle depends on fiber type distribution, fiber typing should accompany measurement of capillary density. To obviate the need for multiple sectioning, we suggest NADH tetrazolium reductase enzyme histochemistry for fiber typing followed (on the same slide) by lectin histochemistry to demonstrate the binding of Ulex europaeus agglutinin, a sensitive marker for endothelium. The method is quick, highly reproducible and gives density estimates comparable to earlier, more tedious methods.     

A novel method to isolate and map endothelial membrane proteins from pulmonary vasculature

Vascular endothelium has attracted extensive attention due to its important role in many physiological and pathological processes. Many methods have been developed to study the components and their functions in vascular endothelium. Here we report a novel approach to investigate vascular endothelium using normal rat lungs as the model. We perfused lung vascular beds with sulfosuccinimidyl-6-(biotinamido) hexanoate, a biotin analog, to label endothelial membrane proteins. The biotinylated proteins were isolated from lung homogenate with immobilized monomeric avidin and confirmed to be highly pure endothelial membrane proteins with little contamination of intracellular proteins. These biotinylated proteins were used as immunogens for development of monoclonal antibodies. Indeed, newly generated monoclonal antibodies have revealed different expression patterns of proteins across tissues. Some proteins were found highly specifically expressed to capillary vessels of pulmonary vasculature. This method has also been proven useful for investigating vasculature of other organs, as this study explored. vascular endothelium; biotinylation; tissue specific; monoclonal antibodies     

Perfusion studies of steady flow in poroelastic myocardium tissue

The behaviour of the heart has always elicited interest and particularly the study of its myocardium, as 5-10% of the blood pumped by the heart is passed through the coronary arteries to the myocardium itself. An in-depth investigation of the myocardium behaviour is useful. The present work aims to investigate how myocardium perfusion is influenced by myocardial stress and diseased states, and in general by LV pumping abnormalities. LV myocardial perfusion can then serve as a possible index of the capacity of the LV to respond to its work demand, and thus of the risk of heart failure. The poroelastic analysis of the myocardium based on finite element method (FEM) for regional perfusion through a rectangular element with various physiological ranges of loading conditions was studied.     

In Vivo Study of Vitellogenin-Gold Transport in the Ovarian Follicle and Oocyte of Xenopus laevis

The transport of injected vitellogenin (VTG)-gold in the ovarian follicle and developing oocyte in Xenopus is described. The gold particles reached the extracellular spaces of the theca and interfollicular spaces within 1 and 2 hr, respectively, after a tracer injection at 20°C. The tracers moved through channels between the constitutive cells of both the capillary endothelium and the follicle cell layer.
Compartments in the peripheral cytoplasm of vitellogenic oocytes at stage IV, which relate to yolk formation, seemed to be segregated as follows: (a) internalization compartment consisting of coated pits and vesicles of the oolemma covering the oocyte "macrovilli", (b) transport compartment of endosomes and multivesicular endosomes in the oocyte cortex, and (c) crystallization compartment of primordial yolk platelets (PYP) in the sub-cortical region. The gold particles appeared in the internalization and transport compartments at 3–6 hr after the tracer injection and in the cystallization compartment at 12–18 hr. The VTG, internalized by receptor-mediated endocytosis, was transferred from coated vesicles to multivesicular endosomes by vesicle-to-vesicle fusion. VTG crystallization took place in globular-shaped PYPs of about 1 μm. At 24 hr after the tracer injection, the gold particles appeared in completely crystallized yolk platelets, most of them clustered in the superficial layer and some integrated into the crystals.     

Cultivation of microvascular endothelial cells from human preputial skin

A procedure is described for the isolation and cultivation of microvascular endothelium from human skin. Neonatal foreskins are pooled, washed, minced, and dissociated by a mixture of collagenase and dispase. Microvascular endothelium, liberated in the form of intact capillary fragments, is incompletely separated from fibroblasts and epidermal cells by sieving through nylon mesh, followed by velocity sedimentation on 5% bovine serum albumin. The endothelium-enriched fraction has been maintained in primary culture for up to 3 weeks. The resulting epithelioid colonies have been characterized morphologically by both light and transmission electron microscopy and manifest all of the structural features that distinguish other, large-vessel endothelia in culture. In addition, immunohistochemical studies using an indirect fluorescent antibody technique demonstrate that these cells contain the endothelium-specific product, Factor VIII antigen.     

Localization of mammary-derived growth inhibitor in capillary endothelial cells of the bovine mammary gland

Mammary-derived growth inhibitor (MDGI) has previously been localized in the mammary parencyma, dependent on the stage of differentiation of the mammary gland. Here, we have elucidated the distribution of MDGI in the mammary stroma by a combined immunohisto-and cytochemical analysis with antibodies raised against MDGI. Distinct staining of capillary endothelial cells has been revealed. Although its subcellular distribution resembles former observations in secretory epithelial cells, the expression of MDGI in capillary endothelial cells clearly precedes that in secretory epithelial cells. On the other hand, no endothelial MDGI staining has been detected in bovine heart, which contains a fatty acid-binding protein almost identical to MDGI. The localization of MDGI in the mammary capillary endothelium is discussed in terms of its possible involvement in the intracellular transport of hydrophobic ligands or in the regulation of endothelial cell proliferation.