Lectin Binding Patterns in Normal Liver, Chronic Active Hepatitis, Liver Cirrhosis, and Hepatocellular Carcinoma An Immunohistochemical and Immunoelectron Microscopic Study

We studied the binding patterns of 14 lectins in human normal and cirrhotic liver (LC) tissues and hepatocellular carcinomas (HCC) using the ABC method. Lectins were divided into 4 groups according to their binding patterns in normal tissues: (A) PHA, MPA, LcH, RCA I, and WGA, which bound to hepatocytes and all three types of sinusoidal cells; (B) BPA, GS-I, PNA, and SBA, which bound to Kupffer cells and endothelia of interlobular arteries and veins and bile duct epithelia in the portal tract, but not to hepatocytes; (C) UEA-I, which bound only to endothelia of interlobular arteries and veins and bile duct epithelia in the portal tract; (D) LBA, Lotus, LPA, and SJA, which showed no binding. Thus group B lectins may be useful markers of Kupffer cells. Only electron microscopic examination revealed the precise binding sites of lectins in sinusoidal cells and hepatocytes. Hepatocyte cell surface polarities demonstrated by lectin binding in LC and HCC were different from those in the normal liver. The binding pattern of PHA to LC hepatocytes changed from a membranous to both a membranous and a cytoplasmic pattern, and that of LcH to HCC cells changed to dot-like staining in the cytoplasm. These changes of polarities in LC and HCC might be caused by changes in the distribution of lectin binding carbohydrates or by the altered glycosylation of glycoconjugates. Acta Pathol Jpn 42: 566–572, 1992.     

Interleukin-12-induced adhesion molecule expression in murine liver.

Systemically administered interleukin (IL)-12 causes liver inflammation in mice characterized by Kupffer cell proliferation and hypertrophy, hepatocyte necrosis, and multifocal accumulations of leukocytes in the hepatic parenchyma and around portal tracts and central veins. We have used both immunohistochemical staining and radiolabeled antibody quantitation to examine adhesion molecule expression in the livers of mice dosed daily with murine IL-12. Cells infiltrating livers of IL-12-treated mice were primarily mononuclear leukocytes expressing LFA-1, VLA-4, MAC-1, and CD18 adhesion molecules but little L-selectin. Kupffer cells constitutively expressed LFA-1 and smaller amounts of MAC-1, and high levels of ICAM-1 were constitutively expressed by liver sinusoidal lining cells, portal tract, and central vein endothelia. With IL-12 treatment, existing ICAM-1 expression was up-regulated and de novo expression occurred along bile duct epithelia. VCAM-1 levels were dramatically increased, with induced expression occurring along portal tract and central vein endothelia and scattered bile duct epithelial cells and in aggregations of cells in perivascular areas and the liver parenchyma. Although constitutive expression of E- and P-selectin was negligible, Il-12 induced a moderate rise in E-selectin levels. These increases in adhesion molecule expression may have implications for the therapeutic use of IL-12, especially in patients with liver disease or autoimmune conditions where augmented adhesion molecule expression may be critical to disease pathogenesis.     

Immunocytochemical analysis of HLA class II (DR) antigens in liver disease in man.

The in situ distribution of the major histocompatibility (HLA) class II (DR) antigens was studied in 113 liver biopsy specimens and five livers obtained at necropsy, using monoclonal antibody CR3/43. In 20 normal livers HLA-DR antigens were not detected in bile duct epithelium, hepatocytes, or portal vein endothelium. Normal arteriolar, sinusoidal and central venous endothelium often expressed HLA-DR. Kupffer cells always expressed these antigens. HLA-DR positive spindle cells were identified in the connective tissue of portal tracts, large hepatic veins, and liver capsule: most shared antigens common to all leucocytes and reacted with the histiocytic maker EBM11. Bile duct epithelium expresses HLA-DR in primary biliary cirrhosis, large duct obstruction, and drug induced cholestasis, indicating that HLA-DR positive spindle cells are phenotypically similar to histiocytes.     

Studies on the relationships of IgA to human liver. IgA deposition in non-alcoholic liver diseases

An investigation was conducted to clarify the relationships of IgA to the human liver. Immunocytochemical studies were performed on biopsy specimens from patients with cirrhosis and chronic hepatitis without any apparent history of alcohol abuse. The results showed that 1) a large amount of IgA is associated with the sinusoidal surface of hepatocytes, endothelial cells and Kupffer cells, 2) this IgA contains J chain and can form a complex with secretory component, and 3) this mainly belongs to the IgA1 subclass, 4) IgA in vesicles within hepatocytes and Kupffer cells is always associated with acid phosphatase activity, and 5) IgA containing vesicles within ductular epithelial cells always lack such enzyme activity. We conclude that 1) the IgA bound to the surface of hepatocytes, sinus endothelial cells and Kupffer cells is polymeric IgA1 uncomplexed with SC, and 2) this IgA occasionally enters these cells, and may be degraded in the lysosomes. 3) Polymeric IgA combines with SC in the ductular epithelium and may be secreted into bile. These findings suggest that J chain-linked polymeric IgA bound to the surface of hepatocytes and Kupffer cells has a certain pathological significance in liver diseases and might be involved in the clearance of excess IgA from the circulation.     

Interaction of lectins with human IgE: IgE-binding property and histamine-releasing activity of twelve plant lectins.

We examined the IgE-binding reaction and the histamine-releasing response of basophils to a panel of 12 lectins: concanavalin A (Con A), Lens culinaris hemagglutinin (LcH), Pisum sativum agglutinin (PSA), wheat germ agglutinin (WGA), soybean agglutinin (SBA), Bauhinia purpurea agglutinin (BPA), peanut agglutinin (PNA), Ricinus communis agglutinin I (RCA-I), Lotus tetragonolobus agglutinin (Lotus A), Ulex europeus agglutinin I (UEA-I), phytohemagglutinin E (PHA-E) and phytohemagglutinin L (PHA-L), IgE from allergic patients bound with high affinity to Con A, LcH, PSA, RCA-I and PHA-E, and with lower affinity to WGA, BPA, Lotus A and UEA-I, but they did not bind to SBA, PNA or PHA-L. There was no apparent individual difference in the reactivity of IgE to these lectins between 10 IgE preparations from allergic patients. The binding to these lectins, except Lotus A and UEA-I, were competitively inhibited by the lectin-specific sugars or glycopeptide. Upon stimulation by Con A, LcH, PSA, WGA, RCA-1 and PHA-E, leukocytes from allergic patients showed a significant release of histamine, but cells from IgE-deficient subjects did not respond to these lectins. The histamine-releasing responses by these lectins were also inhibited by specific sugars or glycopeptides.     

New insights into functional aspects of liver morphology

The liver is structurally and functionally complex and has been considered second only to brain in its complexity. Many mysteries still exist in this heterogeneous tissue whose functional unit of the lobule has continued to stump morphologists for over 300 years. The primary lobule, proposed by Matsumoto in 1979, has been gaining acceptance as the functional unit of the liver over other conceptual views because it's based on vessel architecture and includes the classic lobule as a secondary feature. Although hepatocytes comprise almost 80% of the liver, there are at least another dozen cell types, many of which provide "cross-talk" and play important functional roles in the normal and diseased liver. The distribution and functional roles of all cells in the liver must be carefully considered in both the analysis and interpretation of research data, particularly data in the area of genomics and "phenotypic anchoring" of gene expression results. Discoveries regarding the functional heterogeneity of the various liver cell types, including hepatocytes, hepatic stellate cells, sinusoidal endothelia, and Kupffer cells, are providing new insights into our understanding of the development, prevention and treatment of liver disease. For example, functional differences along zonal patterns (centrilobular or periportal) have been demonstrated for sinusoidal endothelium, Kupffer cells, and hepatocytes and can explain the gradients and manifestations of disease observed within lobules. Intralobular gradients of bile uptake, glycogen depletion, glutamine synthetase, and carboxylesterase by hepatocytes; widened fenestrations in centrilobular sinusoidal lining cells; and differences in the components of centrilobular extracellular matrix or function of Kupffer cells have been demonstrated. Awareness of the complexities and heterogeneity of the liver will add to a greater understanding of liver function and disease processes that lead to toxicity, cancer, and other diseases.     

Transendothelial transport (transcytosis) of iron-transferrin complex in the rat liver

To determine the transport pathway of iron-transferrin complex (Fe-TF) into the hepatocyte, we labeled Fe-TF with colloidal gold and perfused rat liver through the portal vein with this probe under different conditions. The tissue was then studied by transmission electron microscopy. At a cold temperature (～ 4°C), the probe bound to the luminal surface of sinusoidal endothelium without internalization. The binding was limited to the endothelium and there was no binding to Kupffer cells or hepatocytes. The binding was inhibitable in the presence of excess soluble Fe-TF, indicating the specificity of the bindings. At 37°C the probe was internalized via a system of coated pits and vesicles. Morphometric analyses of the temporal sequence of events suggested that the probe was transported, in part, across the endothelium via a system of tubules and vesicles and externalized on the abluminal side via a system of coated pits. The probe was then taken up by hepatocytes. Only minimal uptake was noted when gold-labeled bovine serum albumin was used either at the low temperature or at 37°C. The findings suggest that the liver uptake of Fe-TF complex by hepatocytes is a transendothelial phenomenon (transcytosis).     

Localization of Fc receptors on liver sinusoidal endothelium. A histological study by electron microscopy

The localization of Fc receptors for IgG on mouse liver sinusoidal endothelium was studied in tissue sections by light and electron microscopy using peroxidase-antiperoxidase IgG complexes as ligands. Light microscopy revealed that Fc receptors were continuously present along the sinusoidal wall, but absent on the endothelium of the central vein and that of the portal area blood vessels. Electron microscopy revealed Fc receptors on both the luminal and basal aspects of the plasma membrane, far more being present on the former, on the walls of cytoplasmic fenestrae, and abundantly on the walls of coated pits and vesicles of sinusoidal endothelial cells. Fc receptors were found more frequently on sinusoidal endothelial cells than on Kupffer cells. Fat-storing cells lacked the receptors and hepatocytes showed an ambiguous result which was considered to be nonspecific.     

Binding of 125I-endothelin-1 to fat-storing cells in rat liver revealed by electron microscopic radioautography.

Summary Localization of intravenously injected [¹²⁵I]-endothelin-1 was examined in rat liver by light and electron microscopic radioautography. At 10 min after injection, silver grains were localized along the sinusoidal wall, i.e., mostly on the thin processes of fat-storing cells and sinusoidal endothelial cells, and also on the Kupffer cells and the microvilli of hepatocytes. About 35% of the total silver grains were located on the processes of fat-storing cells at 10 min. The grain density (number of silver grains/cell area) of fat-storing cells was three-fold that of Kupffer cells, and 18-fold that of hepatocytes. At 60 min, 60% of the total grains were observed on the fat-storing cells, though the value of grain density was not changed. Silver grains were internalized into the cytoplasm of fat-storing cells and often associated with multivesicular bodies. In contrast, the grain density of endothelial cells and Kupffer cells decreased with time. These results indicate that hepatic fat-storing cells have a considerable number of endothelin-binding sites, and incorporate bound endothelin into cytoplasm.     

Vascular endothelial growth factor, its receptor Flk-1, and hypoxia inducible factor-1alpha are involved in malignant transformation in dysplastic nodules of the liver

Dysplastic nodules (DNs) are regarded as a premalignant lesion of hepatocellular carcinoma (HCC). Sinusoidal capillarization and unpaired arteries are reported in HCC and also to a lesser degree in DN. However, the mechanism and significance of these vascular alterations remain unclear. In this study, these vascular changes were examined with respect to vascular endothelial growth factor (VEGF) and its receptors (Flt-1 and Flk-1), hypoxia inducible factor-1alpha (HIF-1alpha), and CD34, by using 20 surgically resected cases of DNs and 36 cases of conventional HCC. The expression of these molecules was examined immunohistochemically. Although sinusoidal capillarization characterized by CD34 expression was found diffusely in HCC, such changes were found mainly in the areas around the portal tracts and also in other areas in DNs (focal in 6 cases, zonal in 7 cases, and extensive distribution in 7 cases). These capillarized areas were frequently associated with unpaired arteries, and the infiltration of neoplastic hepatocytes into the portal tracts and loss of reticulin fibers in DNs, particularly those with a zonal and extensive distribution. VEGF was diffusely expressed in neoplastic hepatocytes of DNs and HCC. Interestingly, Flk-1 and HIF-1alpha were mostly expressed in endothelial cells and neoplastic hepatocytes in the capillarized areas around portal tracts in DNs, respectively. In conclusion, the capillarized areas with increased numbers of unpaired arteries in DNs may represent an early malignant transformation. Increased expression of Flk-1 and HIF-1alpha associated with VEGF may be involved in sinusoidal capillarization and the increased numbers of unpaired arteries in these areas.     

Expression patterns of leukocyte adhesion ligand molecules on human liver endothelia. Lack of ELAM-1 and CD62 inducibility on sinusoidal endothelia and distinct distribution of VCAM-1, ICAM-1, ICAM-2, and LFA-3.

Vascular expressed adhesion molecules mediate leukocyte reactivity and activation by receptor-ligand binding. A number of different ligand molecules have been identified to mediate the interaction between endothelial cells and leukocyte subpopulations. In this study, the tissue expression of ELAM-1, CD62 (PADGEM, GMP-140), VACM-1 (INCAM-110), ICAM-2, ICAM-1, and LFA-3 was analyzed on various liver endothelial cell types by immunohistology. The results reveal a differential expression of these molecules in normal liver and inflammation or rejection after liver transplantation. The selectins ELAM-1 and CD62 are basally expressed and inducible on portal tract endothelia (arterial and venous) and central vein endothelia with acute and chronic liver inflammation. Sinusoidal endothelia, however, lack this mechanism, even with severe inflammation, as in cases of irreversible rejection and sepsis. Portal and sinusoidal endothelia show a different expression and inducibility of VCAM-1, ICAM-1, ICAM-2, and LFA-3. The differences in expression of adhesion molecules on liver endothelial cell types may reflect their ability to regulate leukocyte trafficking and activation by means of the expression of specific ligand molecules. The inability of sinusoidal endothelia to express selectins may have implications for the pathophysiology of liver graft infiltration.     

IgG immune complex binding to and activation of liver cells. An in vitro study with IgG immune complexes, Kupffer cells, sinusoidal endothelial cells and hepatocytes

BACKGROUND/AIMS: The aim was to study IgG immune complex (IC) binding to isolated hepatocytes, Kupffer cells (KCs) and sinusoidal endothelial cells (SECs). Further, we wished to analyze the capacity of IgG ICs to induce release of reactive oxygen metabolites by the IC-binding liver cells. METHODS: ICs were formed between (125)I-tyramine-cellobiose-labelled dinitrophenyl-conjugated human serum albumin ((125)I-TC-DNP(10)HSA) and polyclonal rabbit IgG antibodies. Binding of ICs to different rat liver cells in suspension was studied at 4 degrees C. Production of reactive oxygen metabolites was measured by luminol-enhanced chemiluminescence at 37 degrees C. RESULTS: IgG mediated binding of (125)I-TC-DNP(10)HSA to both KCs and SECs, but not to hepatocytes. The binding showed saturation kinetics and was blocked by an excess of unlabelled IgG-ICs. IgG-ICs activated KCs, but not SECs, to a chemiluminescence response. CONCLUSIONS: Both KCs and SECs bind IgG-ICs in vitro, probably via Fc receptor interaction. IgG-ICs activate KCs to produce reactive oxygen metabolites. The binding of IgG-ICs to isolated hepatocytes is small.     

Kupffer cell activation and hematopoiesis in the liver of autoimmune MRL-lpr/lpr mice

Hematopoiesis can be induced in the adult murine liver by the administration of macrophage activators. The proliferation of macrophages and extrathymic T cells is spontaneously induced in the liver of autoimmune MRL-lpr/lpr mice, and deeply involved in the development of disease. To study the role of Kupffer cell activation in the induction of hematopoiesis and lymphocyte proliferation in the liver, we histologically analysed the kinetic and spatial relationship between Kupffer cells and hematopoietic cells or lymphocytes. At 5 weeks of age before the onset of disease, there were no appreciable histological changes in the liver. At 7 weeks, Kupffer cells had slightly increased in number, while hematopoietic islands were not yet detected. When disease had fully developed at 14 weeks, Kupffer cells were considerably increased in number and size, and exhibited numerous lysosomes. Hematopoietic cells of erythroid and myeloid series frequently appeared in the sinusoid, and lay in close apposition to Kupffer cells. Promyelocytes further migrated into the space of Disse to cluster there, being surrounded by the stellate cells (or fat-storing cells) and hepatocytes. After maturation, metamyelocytes and mature granulocytes were released into the sinusoidal circulation. Mitotic figures were detected in the cells of both erythroid and myeloid series. Lymphocytes proliferated in various sites such as in the sinusoid lumen, the space of Disse, and interlobular connective tissue, whether associated or not with Kupffer cells. The present results indicate that erythropoiesis, granulopoiesis, and lymphocyte proliferation are induced in the liver of MRL-lpr/lpr mice and are closely associated with Kupffer cell activation.     

Binding kinetics of monomeric and aggregated IgG to Kupffer cells and hepatocytes of mice

The binding kinetics of human monomeric IgG and stable heat-aggregated IgG (A-IgG) to Fc receptors of hepatocytes and Kupffer cells isolated from mice was studied. After injection of radiolabelled proteins the 60-70% of hepatic uptake was recovered in parenchymal cells (hepatocytes). In experiments in vitro the A-IgG bound in larger amounts to hepatocytes and Kupffer cells than monomeric IgG. The association rate constants of aggregates were somewhat higher for Kupffer cells than for hepatocytes whereas the percentage uptake of aggregates by Kupffer cells was only 5-15% of that of hepatocytes. The equilibrium constants of aggregates binding to both cells amounted to 0.4-1 X 10(8) M-1 for A-IgG compared with an equilibrium constant for monomeric IgG of 1-2 X 10(7)M-1. The maximum number of IgG and A-IgG molecules bound per cell was higher on hepatocytes (mean 14 X 10(6)) than on Kupffer cells (mean 2 X 10(5)) which is in agreement with the higher binding capacity of hepatocytes for these proteins observed in vivo and in vitro experiments. The ability to compete for receptor binding seemed to reside exclusively in the Fc portion of IgG since F(ab')2 fragments of IgG failed to inhibit labelled monomeric IgG or A-IgG. The receptor seems to be specific for IgG since unlabelled monomeric IgA demonstrated no binding inhibition of labelled IgG or A-IgG on hepatocytes and Kupffer cells. The overall results further suggest that hepatocytes might through Fc receptors play a collaborative role with the mononuclear phagocytic system in the clearance of circulating immune complexes.     

Modifications of the sinusoidal barrier in a model of postsinusoidal hypertension in the rat. An ultrastructural study of endothelial cells

Sinusoids and sinusoidal cells were examined by light and electron microscopy, using a rat model of postsinusoidal hypertension. One month after partial ligation of the vena cava (PLVC) above the hepatic veins, subcapsular hemorrhagic areas were visible with proliferation of hepatic veins; in non hemorrhagic areas, sinusoidal congestion was found. Postsinusoidal hypertension led to a significant increase in sinusoidal volume and to major abnormalities of the endothelium such as endothelial processes and pouches with numerous diaphragmed fenestrae; some red blood cells could be seen in these pouches. Endothelial cells sent out processes in between hepatocytes. Complete and incomplete pseudo-neolumens were found near sinusoids. Numerous Kupffer cells were located either in the sinusoidal barrier or infiltrating the Disse space close to extravasated red blood cells and perisinusoidal cell processes. 18 months after PLVC, lesions were much the same except for the presence of red blood cells in the Disse space.     

A new monoclonal antibody, UFT-4, reacting with rat Kupffer cells. Immunohistochemical and immunoelectron microscopical analysis with reestimation of the reticuloendothelial system

A new monoclonal antibody, designated UFT-4, reacting with rat Kupffer cells, was produced using sinusoidal liver-cell fraction as an immunogen. Immunohistochemically, UFT-4 reacted with Kupffer cells, interdigitating cells (IDCs), sinus endothelial cells of the spleen, a proportion of reticulum cells, smooth muscle fibers, choroid plexus epithelia and some macrophages. Immunoelectron microscopy disclosed two types of intracytoplasmic positivity: a striated type and a diffuse type. Both appeared to depend on variations in the quantity and distribution of the same antigen. On the other hand, UFT-4 gave a negative result for blood monocytes and most macrophages in lymphatic sinuses, lymphoid follicles, splenic red pulp and loose connective tissue. Cells positive for UFT-4 were mostly considered to belong to a narrow spectrum of the classical reticuloendothelial system, explaining the close relationship existing between some endothelia and some macrophages or reticulum cells. SDS-PAGE analysis of immunoprecipitates showed that the antigen reacting with UFT-4 was of molecule of 36-42 kDa under reducing conditions in the presence of 2-mercaptoethanol. The present results suggest that UFT-4 will be very useful for the study of Kupffer cells and for reconsidering their origin and destination.     

An ultrastructural study of the liver in erythropoietic protoporphyria

An ultrastructural investigation of the liver was performed in two patients with erythropoietic protoporphyria. There were many protoporphyrin crystals in the hepatocytes, Kupffer cells, bile canaliculi, epithelia of bile ducts, and sinusoidal endothelial cells and also free within sinusoids. In hepatocytes, these deposits were composed of granular amorphous materials and numerous slender, straight, or slightly curved needle-like crystals aligned in radial orientation. They were randomly distributed in the cytoplasm and completely replaced other cytoplasmic structures. Some crystals lay free in the cytoplasm and others were surrounded by a single membrane. In the bile canaliculi, severe alterations could be observed. Some of the bile canaliculi were filled with amorphous, noncrystalline pigments, and lumina were enlarged with loss of micro-villi. In addition, despite the absence of protoporphyrin deposits, there were many dilated bile canaliculi. The microfilamentous network around such dilated bile canaliculi was no longer evident, suggesting the depolymerization of actin filaments, which could lead to bile excretory disturbances. The bile duct epithelia showed focal apical membrane bleb formation. The functional or structural alterations of the sinusoidal endothelial cells by the protoporphyrin crystals might lead to the hepatic disturbances. These ultrastructural findings of the liver might contribute to the understanding of the pathogenesis of complicated liver disease in erythropoietic protoporphyria.     

Functional differences between sinusoidal endothelial cells and interlobular or central vein endothelium in rat liver

The fine topological relationship between sinus-lining endothelial cells (SLE) and vessel-lining endothelial cells (VLE) at the opening portion of sinusoids into central or interlobular veins of rat liver was studied by a comparison of morphological and functional properties of both types of cells. Three minutes after intravenous injection of formalin-denatured albumin conjugated with horseradish peroxidase (HRP-FDA), liver was perfused with fixative. Chopped sections of the liver (50 micron thick) were incubated in diaminobenzidine-H2O2 medium, followed by processing for electron microscopy. The HRP-FDA was localized in endocytotic vesicles and vacuoles of the SLE and Kupffer cells but not of the VLE lining interlobular or central veins or interlobular arteries. In the opening portion of the sinusoids into these veins, the attenuated cytoplasmic extensions of the SLE containing positive vesicles were in direct contact with squamous process of the VLE having no positive vesicles. The contact was mediated by overlapping junctions. No intermediate cell type between the SLE and VLE in this region or other portions was noted. The results indicate that the habitat of the SLE is exactly isolated from that of the VLE in rat liver and at the transitional portion from sinusoids to veins or arteries they are directly connected with each other by overlapping junctions.     

Binding of the blood group-reactive lectins to human adult kidney specimens

The binding of a panel of blood group-reactive lectins to frozen sections of human kidney was studied with a special emphasis on reactivity with endothelia and basement membranes. The blood group A-reactive lectins, all specific for alpha-D-N-acetylgalactosamine (GalNAc), Helix aspersa (HAA), Helix pomatia (HPA), and Griffonia simplicifolia I-A4 (GSA-I-A4) agglutinins bound to the endothelium in specimens with blood groups A and AB. In other samples, these lectins reacted predominantly with tubular basement membranes, as well as with certain tubules. Both Dolichos biflorus (DBA) and Vicia villosa agglutinins (VVA), reported to react with blood group A1 substance, failed to reveal endothelia in most specimens, but bound differently to tubules in all blood groups. The blood group B-reactive lectins, specific for alpha-D-galactose (alpha-Gal) or GalNAc, respectively, GSA-I-B4 and Sophora japonica agglutinin (SJA), bound to the endothelia in specimens from blood group B or AB and in other specimens bound only to certain tubules. Among the blood group O-reactive lectins, specific for alpha-L-fucose (Fuc), Ulex europaeus I agglutinin (UEA-I) conjugates, but not other lectins with a similar nominal specificity, bound strongly to endothelia in specimens with blood group O. The UEA-I conjugates bound distinctly more faintly to endothelia in specimens of other blood groups. The present results indicate that lectins, binding to defined blood group determinants, react with endothelia in specimens of the respective blood group status. Furthermore, they suggest that basement membranes and some tubules in the human kidney show a distinct heterogeneity in their expression of saccharide residues, related to their blood group status.     

Pathology of the liver sinusoids

The hepatic sinusoids comprise a complex of vascular conduits to transport blood from the porta hepatis to the inferior vena cava through the liver. Under normal conditions, portal venous and hepatic artery pressures are equalized within the sinusoids, oxygen and nutrients from the systemic circulation are delivered to the parenchymal cells and differentially distributed throughout the liver acini, and proteins of liver derivation are carried into the cardiac/systemic circulation. Liver sinusoid structures are lined by endothelial cells unique to their location, and Kupffer cells. Multifunctional hepatic stellate cells and various immune active cells are localized within the space of Disse between the sinusoid and the adjacent hepatocytes. Flow within the sinusoids can be compromised by physical or pressure blockage in their lumina as well as obstructive processes within the space of Disse. The intimate relationship of the liver sinusoids to neighbouring hepatocytes is a significant factor affecting the health of hepatocytes, or transmission of the effects of injury within the sinusoidal space. Pathologists should recognize several patterns of injury involving the sinusoids and surrounding hepatocytes. In this review, injury, alterations and accumulations within the liver sinusoids are illustrated and discussed.