Immunolocalization of a fibronectin-binding proteoglycan (PG-P1) immunologically related to HSPG2/perlecan in normal and fibrotic human liver

Plasma cells and the chronic nonsuppurative destructive cholangitis of primary biliary cirrhosis

There has been increased interest in the role of B cells in the pathogenesis of primary biliary cirrhosis (PBC). Although the vast majority of patients with this disease have anti-mitochondrial antibodies, there is no correlation of anti-mitochondrial antibody titer and/or presence with disease severity. Furthermore, in murine models of PBC, it has been suggested that depletion of B cells may exacerbate biliary pathology. To address this issue, we focused on a detailed phenotypic characterization of mononuclear cell infiltrates surrounding the intrahepatic bile ducts of patients with PBC, primary sclerosing cholangitis, autoimmune hepatitis, chronic hepatitis C, and graft-versus-host disease, including CD3, CD4, CD8, CD20, CD38, and immunoglobulin classes, as well as double immunohistochemical staining for CD38 and IgM. Interestingly, CD20 B lymphocytes, which are a precursor of plasma cells, were found in scattered locations or occasionally forming follicle-like aggregations but were not noted at the proximal location of chronic nonsuppurative destructive cholangitis. In contrast, there was a unique and distinct coronal arrangement of CD38 cells around the intrahepatic ducts in PBC but not controls; the majority of such cells were considered plasma cells based on their expression of intracellular immunoglobulins, including IgM and IgG, but not IgA. Patients with PBC who manifest this unique coronal arrangement were those with significantly higher titers of anti-mitochondrial antibodies.

CONCLUSION

These data collectively suggest a role for plasma cells in the specific destruction of intrahepatic bile ducts in PBC and confirm the increasing interest in plasma cells and autoimmunity.

Proteoglycans mediate malaria sporozoite targeting to the liver

Malaria sporozoites are rapidly targeted to the liver where they pass through Kupffer cells and infect hepatocytes, their initial site of replication in the mammalian host. We show that sporozoites, as well as their major surface proteins, the CS protein and TRAP, recognize distinct cell type-specific surface proteoglycans from primary Kupffer cells, hepatocytes and stellate cells, but not from sinusoidal endothelia. Recombinant Plasmodium falciparum CS protein and TRAP bind to heparan sulphate on hepatocytes and both heparan and chondroitin sulphate proteoglycans on stellate cells. On Kupffer cells, CS protein predominantly recognizes chondroitin sulphate, whereas TRAP binding is glycosaminoglycan independent. Plasmodium berghei sporozoites attach to heparan sulphate on hepatocytes and stellate cells, whereas Kupffer cell recognition involves both chondroitin sulphate and heparan sulphate proteoglycans. CS protein also interacts with secreted proteoglycans from stellate cells, the major producers of extracellular matrix in the liver. In situ binding studies using frozen liver sections indicate that the majority of the CS protein binding sites are associated with these matrix proteoglycans. Our data suggest that sporozoites are first arrested in the sinusoid by binding to extracellular matrix proteoglycans and then recognize proteoglycans on the surface of Kupffer cells, which they use to traverse the sinusoidal cell barrier.

Expression and potential role of the extracellular matrix in hepatic ontogenesis: a review

Studies from a number of laboratories have provided information on the temporal and spatial expression of a variety of extracellular matrix (ECM) components in the developing liver and insight into their potential roles in hepatogenesis. Collagen type IV and laminin are present in the basement membranes of the capsular mesothelium, vascular structures of the portal and hepatic vein branches, and the ductular elements of the developing liver. The mesothelial, vascular, and ductular epithelial cells synthesize laminin and type IV collagen. In contrast, fibronectin and type I collagen are restricted to the adjacent or surrounding interstitium of those ductal and vascular elements, but are not within the basement membrane proper. The hepatic perisinusoidal space (Space of Disse) of the fetal rat develops a delicate extracellular matrix by 12.5 days of gestation, which is characterized by banded collagen fibrils and bundles associated with filamentous and flocculent material. Fibronectin, laminin, and collagen types I, III, and IV are present in the developing perisinusoidal space by this early gestational date, with laminin being the most prevalent component detected. The laminin chains localized to that region in the fetal/neonatal period are alpha 2, beta 1, beta 2, and gamma 1, whereas the alpha 1 chain of laminin is absent from the developing Space of Disse. Similar data have been reported on the laminin phenotype in the perisinusoidal space during hepatic regeneration. Electron microscopy immunohistochemistry studies have demonstrated that the sinusoidal lining cells and hepatocytes synthesize these ECM proteins during hepatogenesis. By 6 to 8 weeks of postnatal life, laminin is not detectable in the perisinusoidal space. Both the transient expression of laminin and the similarity of the laminin chain phenotype expressed in the perisinusoidal space in the developing and regenerating liver suggests a role for this protein in the organization of the hepatic lobule in those forms of hepatic morphogenesis.

Expression, localization and alternative splicing pattern of fibronectin messenger RNA in fibrotic human liver and hepatocellular carcinoma

BACKGROUND/AIMS

Fibronectin is a multifunctional glycoprotein and plays important roles in cell-to-cell or cell-to-matrix interaction. The molecular and functional diversity of fibronectin arises from alternative splicing of pre-mRNA at three variable regions, termed ED-A, ED-B and IIICS. Cellular fibronectin with ED-A and ED-B regions has different biological activities from plasma fibronectin lacking these regions. This study was aimed at investigating the type-specific expression of fibronectin in human liver diseases.

METHODS

Immunohistochemistry with anti-total and anti-cellular fibronectin monoclonal antibodies, in situ hybridization with cDNA probes detecting common and ED-A regions and RT-PCR to amplify each variable region were performed in 35 specimens, including 4 control, 16 chronic hepatitis, 7 liver cirrhosis and 8 hepatocelular carcinoma.

RESULTS

In control liver, there were slight deposits of cellular fibronectin [ED-A(+)fibronectin] in portal areas. In chronic hepatitis, it was strongly deposited at the margin of the fibrously enlarged portal areas where new collagen fibers were formed. Cellular fibronectin was evenly and abundantly accumulated in fibrotic septa in liver cirrhosis, and in fibrotic septa and capsules of tumor nodules in hepatocellular carcinoma. In control liver, cellular fibronectin mRNA was localized in a few hepatocytes and non-parenchymal cells around central veins, and was increased in the same cell populations near fibrously enlarged portal areas as hepatic fibrosis progressed. In hepatocellular carcinoma, it was expressed in most hepatoma cells. Fibronectin mRNA with three variable regions was detectable by RT-PCR in control liver as well as in each disease group.

CONCLUSIONS

The expression of cellular fibronectin was increased in fibrotic human liver and hepatocellular carcinoma. In human liver, both non-parenchymal cells and hepatocytes participated together in cellular fibronectin production. In hepatocellular carcinoma, hepatoma cells were the main producer. Our results indicate that, in human liver, cellular fibronectin may participate in the hepatic fibrogenesis and in the malignant phenotypes of hepatocellular carcinoma.