Altered expression and function of hepatocyte gap junctions after common bile duct ligation in the rat

Gap junction channels allow intercellular exchange of ions and small molecules between adjacent cells. Such communication coordinates cellular and organ function in tissues, although it is unclear if altered gap junction expression and communication contribute to organ dysfunction in pathological states. We examined the immunofluorescent (IF) localization and mRNA and protein levels of the two hepatocyte gap junction proteins connexin 32 and connexin 26, after hepatic injury induced by common bile duct ligation (CBDL) in the rat. Intercellular communication was measured by comparing gap junction-mediated coordination of hormone-induced Ca2+ signals in isolated rat hepatocyte couplets from control and CBDL animals. Connexin 32 plasma membrane IF, protein, and mRNA levels decreased markedly early after CBDL and remained low at 14 days. Connexin 26 plasma membrane IF and protein levels also decreased markedly after CBDL, but mRNA levels rose, and a partial return in membrane IF and protein levels was noted at 9 and 14 days. Coordination of vasopressin-induced Ca2+ signals between cells in isolated rat hepatocyte couplets 1 day after CBDL was significantly impaired compared with controls. These results demonstrate that hepatocyte gap junction communication is impaired early after CBDL because of decreased connexin protein levels. Disruption of gap junctions after CBDL may contribute to loss of hepatic functions that depend on gap junction communication.

Multistep mechanism of polarized Ca2+ wave patterns in hepatocytes

The spatial organization of cytosolic Ca2+ (Ca2+i) signals is thought to be important for regulation of cell function. In epithelial cells, the involvement of inositol 1,4,5-trisphosphate (IP3)-mediated Ca2+ release in evoking Ca2+i signals is appreciated, but the location of IP3-sensitive Ca2+ stores and the role of Ca(2+)-induced Ca2+ release (CICR) for Ca2+ signaling are less defined. Here, we demonstrate that IP3 receptors are localized to the apical region in hepatocytes. We also show that hormone-induced Ca2+i waves propagate across the cell at a rate that depends on mobilization of Ca2+ stores that are sensitive to caffeine, ryanodine, and dantrolene, and that these agents, at concentrations that inhibit CICR, decrease the magnitude of Ca2+i signals. Furthermore, Ca2+i wave speed is not reduced in Ca(2+)-free medium. These findings suggest that Ca2+i signals in epithelial cells begin as apical-to-basal Ca2+i waves that result from sequential release of Ca2+, first from IP3-sensitive stores in the apex and then from Ca(2+)-sensitive stores distributed across the remainder of the cell.

Localization of the type 3 inositol 1,4,5-trisphosphate receptor in the Ca2+ wave trigger zone of pancreatic acinar cells

Agonist-induced cytosolic Ca2+ (Ca2+i) signals begin as apical-to-basal Ca2+i waves in pancreatic acinar cells and in other polarized epithelia. However, the basis of this polarized Ca2+i signaling pattern is unknown. Here we use immunocytochemistry to demonstrate that the type 3 inositol trisphosphate receptor is localized to the extreme apex of pancreatic acinar cells, the region which corresponds to the trigger zone from which Ca2+i signals originate in this cell type (Kasai, H., Li, Y.X., and Miyashita, Y. (1993) Cell 74, 669-677). We also show that inositol trisphosphate-mediated Ca2+ release induces amylase release from permeabilized pancreatic acini. Since Ca2+i signals begin by inositol trisphosphate-mediated Ca2+ release, these findings suggest that localization of the type 3 inositol trisphosphate receptor to the trigger zone is responsible for the generation of apical-to-basal Ca2+i waves, and that this organization may be important for regulating apical exocytosis in pancreatic acinar cells.

Altered expression and localization of the tight junction protein ZO-1 after common bile duct ligation

Hepatocyte tight junctions form the intercellular barrier between bile and blood. Cholestasis due to common bile duct ligation (CBDL) results in structural changes in the tight junction (TJ) and an overt paracellular leak, although the molecular basis for these alterations is undefined. Using the epithelial isoform of the TJ protein ZO-1 (ZO-1 alpha +) as a marker for molecular changes in hepatocyte TJs, we investigated the effects of CBDL on ZO-1 alpha + immunofluorescence (IF) localization and on ZO-1 alpha + mRNA and protein expression over 2 wk of CBDL. ZO-1 alpha + IF staining was altered after 2 days of CBDL and appeared to accumulate in pericanalicular regions after 7 and 9 days. Quantitative immunoblotting and ribonuclease protection revealed a marked increase in hepatic ZO-1 alpha + protein expression and ZO-1 alpha + mRNA levels, respectively. In contrast to changes in ZO-1 alpha + IF, which occurred throughout the lobule, and changes in mRNA and protein expression, which were maximal after 9 days of ligation, the maximal hepatocyte proliferation occurred within 2 days after CBDL and was confined to periportal regions. CBDL results in altered hepatic localization and increased expression of the TJ protein ZO-1 alpha + and appears to represent a specific response by hepatocytes to pathological junction injury independent of cell proliferation.

Structure, regulation, and pathophysiology of tight junctions in the gastrointestinal tract

The tight junction, or zonula occludens, forms an intercellular barrier between epithelial cells within the gastrointestinal tract and liver and, by limiting the movement of water and solutes through the intercellular space, maintains the physicochemical separation of tissue compartments. The paracellular barrier properties of junctions are regulated and quite different among epithelia. The junction also forms an intramembrane barrier between the apical and basolateral membrane domains, contributing to segregation of biochemically distinct components of these plasma membrane surfaces. Here we briefly review three rapidly developing areas of medically relevant basic knowledge about the tight junction. First, we describe the presently incomplete knowledge of the molecular structure of the tight junction as a framework for understanding its functional properties. Second, we consider experimental evidence defining how the barrier properties of junctions are physiologically regulated and, third, how barrier properties are specifically altered in, and contribute to, pathologic processes affecting epithelia.

Hepatic toxicity of vitamin A and synthetic retinoids

Vitamin A and synthetic retinoids have recently been used increasingly in a variety of health related concerns. Hepatic toxicity is an uncommon but serious side-effect of several Vitamin A derivatives which may lead to cirrhosis. This review will focus on the clinical and pathologic findings of hepatic involvement in chronic hypervitaminosis A and on the evidence concerning the potential hepatotoxicity of currently available synthetic retinoids.

Effects of exogenous insulin, glucagon, and somatostatin on islet hormone secretion in the perfused chicken pancreas

The effects of exogenous insulin were examined in the isolated perfused chicken pancreas with the duodenum excluded. At low background glucose (50 mg/dl), exogenous insulin infused at a concentration of 20,000 microU/ml elicited clear stimulation of somatostatin secretion while simultaneously inhibiting glucagon release. When the background glucose concentration was elevated to 750 mg/dl, exogenous insulin, had no effect on either somatostatin or glucagon release. When graded doses of exogenous insulin were infused into the chicken pancreas at low background glucose, low concentrations (200 microU/ml) had little effect on somatostatin or glucagon release, but higher concentrations (2000 and 20,000 microU/ml) had clear effects on both somatostatin and glucagon secretion. Glucagon infused at 100 ng/ml stimulated both insulin and somatostatin release. When somatostatin was infused at 25 ng/ml, clear inhibition of glucagon was seen with insulin inhibited to a lesser extent. This study supports the notion of a negative feedback relation between B and D-cells of the pancreatic islets and suggests a paracrine mediation.