Aggresome formation in liver cells in response to different toxic mechanisms: role of the ubiquitin-proteasome pathway and the frameshift mutant of ubiquitin.

Aggresomes form in cells when intracellular proteins undergo conformational changes, as in so-called conformational diseases. This phenomenon has been observed in the liver and brain and in cell culture in response to abnormal protein formation, such as mutant proteins. In the case of the brain the frameshift mutant ubiquitin (UBB+1) is involved. Mallory body formation in the liver is one example of this phenomenon in vivo. Mallory body formation is common in a variety of liver diseases of diverse pathogenesis. The study of the Mallory body forming model indicated that drug-conditioned hepatocytes form Mallory bodies when mice are given colchicine, ethanol, okadaic acid, or exposure to heat shock. These findings suggest that aggresome formation is a common pathway of liver injury due to diverse mechanisms. To further characterize the role of this common pathway, drug-primed mice were exposed to different types of liver injury, i.e., using such drugs as thioacetamide, galactosamine, tautomycin, and the proteasome inhibitor PS341. Mallory body formation was induced by treatment with all the toxins tested, giving credence to the proposal that aggresome formation in the liver is a common pathway in response to different primary mechanisms of liver injury. The frameshift mutant UBB+1 was invariably found to colocalize with ubiquitin in the Mallory body, indicating its essential involvement in the mechanism of MB formation.

Keratin-mediated resistance to stress and apoptosis in simple epithelial cells in relation to health and disease.

Epithelial cells such as hepatocytes exhibit highly polarized properties as a result of the asymmetric distribution of subsets of receptors at unique portions of the surface membrane. While the proper targeting of these surface receptors and maintenance of the resulting polarity depend on microtubules (MTs), the Golgi sorting compartment, and different actin-filament networks, the contribution of keratin intermediate filaments (IFs) has been unclear. Recent data show that the latter cytoskeletal network plays a predominant role in providing resistance to various forms of stress and to apoptosis targeted to the surface membrane. In this context, we first summarize our knowledge of the domain- or assembly-related features of IF proteins and the dynamic properties of IF networks that may explain how the same keratin pair K8/K18 can exert multiple resistance-related functions in simple epithelial cells. We then examine the contribution of linker protein(s) that integrate interactions of keratin IFs with MTs and the actin-cytoskeleton network, polarity-dependent surface receptors and cytoplasmic organelles. We next address likely molecular mechanisms by which K8/K18 can selectively provide resistance to a mechanical or toxic stress, or to Fas-mediated apoptosis. Finally, these issues on keratin structure-function are examined within a context of pathological anomalies emerging in tissue architecture as a result of natural or targeted mutations, or posttranslational modifications at specific amino acid residues. Clearly. the data accumulated in recent years provide new and significant insights on the role of K8/K18, particularly under conditions where polarized cells resist to stressful or apoptotic insults.

Simple epithelium keratins 8 and 18 provide resistance to Fas-mediated apoptosis. The protection occurs through a receptor-targeting modulation.

Keratins 8 and 18 belong to the keratin family of intermediate filament (IF) proteins and constitute a hallmark for all simple epithelia, including the liver. Hepatocyte IFs are made solely of keratins 8 and 18 (K8/K18). In these cells, the loss of one partner via a targeted null mutation in the germline results in hepatocytes lacking K8/K18 IFs, thus providing a model of choice for examining the function(s) of simple epithelium keratins. Here, we report that K8-null mouse hepatocytes in primary culture and in vivo are three- to fourfold more sensitive than wild-type (WT) mouse hepatocytes to Fas-mediated apoptosis after stimulation with Jo2, an agonistic antibody of Fas ligand. This increased sensitivity is associated with a higher and more rapid caspase-3 activation and DNA fragmentation. In contrast, no difference in apoptosis is observed between cultured K8-null and WT hepatocytes after addition of the Fas-related death-factors tumor necrosis factor (TNF) alpha or TNF-related apoptosis-inducing ligand. Analyses of the Fas distribution in K8-null and WT hepatocytes in culture and in situ demonstrate a more prominent targeting of the receptor to the surface membrane of K8-null hepatocytes. Moreover, altering Fas trafficking by disrupting microtubules with colchicine reduces by twofold the protection generated against Jo2-induced lethal action in K8-null versus WT hepatocytes. Together, the results strongly suggest that simple epithelium K8/K18 provide resistance to Fas-mediated apoptosis and that this protection occurs through a modulation of Fas targeting to the cell surface.

Early perturbations in keratin and actin gene expression and fibrillar organisation in griseofulvin-fed mouse liver.

BACKGROUND/AIMS: Long-term feeding of mice with a diet containing griseofulvin results in the formation of Mallory bodies, keratin K8 and K18 containing aggregates in hepatocytes. These bodies are biochemically and morphologically identical to the Mallory bodies that emerge in several human liver disorders. The aim of this study was to examine the contribution of K8 and K18 and actin to Mallory body formation. METHODS: Mice were fed griseofulvin over a period ranging from 1 day to 20 months. Hepatocyte morphology was monitored by immunocytochemistry, gene expression by Northern and run-off transcription assays, and protein level by Western blotting. RESULTS: Griseofulvin feeding induced a series of morphological alterations in hepatocytes that could be grouped into 3 phases: appearance of cholestasis during the first week (phase I), partial hepatocyte recovery at 3 months (phase II), and development of typical Mallory bodies after 3 to 5 months (phase III). All these cellular alterations were associated with perturbations in keratin and actin fibrillar status, coupled with increases in K8, K18 and actin mRNA steady-state level and, in K8 and K18 protein content. The transcriptional activity of the genes was not affected. CONCLUSIONS: Perturbations in keratin and actin gene expression and fibrillar organisation constitute early events in the griseofulvin-induced pathological process that in the long-term leads to Mallory body formation. The higher keratin and actin mRNA levels reflect significant increases in mRNA stability taking place at the early phase of griseofulvin intoxication in hepatocytes.

Zonal induction of mixed lineage kinase ZPK/DLK/MUK gene expression in regenerating mouse liver.

ZPK/DLK/MUK is a serine/theronine kinase believed to be involved in the regulation of cell growth and differentiation. To further explore the suggested participation of ZPK/DLK/MUK in this process, we examined the expression and cellular localization of ZPK/DLK/MUK mRNA in regenerating mouse liver following partial hepatectomy by ribonuclease protection assay and in situ hybridization. The steady-state level of APK/DLKMUK mRNA was very low in normal and sham-operated mouse livers, whereas a marked and transient increase was observed in the regenerating liver. While ZPK/DLK/MUK mRNAs were rarely detected in hepatocytes from all zones of the normal liver, hepatocytes of regenerating liver exhibit a gradient of expression ranging from low in the periportal zone, to intermediate in the mid-zone, to high in the pericentral zone. These findings demonstrate a transient stimulation of ZPK/DLK/MUK gene expression that correlates with the growth response of hepatocyte subpopulations in regenerating liver.

Mallory body formation by ethanol feeding in drug-primed mice.

Drug-primed mice, created by a 5-month feeding of diethyl-1,4-dihydro-2,4,6-trimethyl-3,5-pyridinedicarboxylate (DDC), followed by a 1-month withdrawal, were refed ethanol or isocaloric dextrose (control) diets intragastrically for 7 days. The formation of Mallory bodies (MBs) was monitored by immunofluorescence and immunoperoxidase microscopy using antibodies to cytokeratin and ubiquitin, and also by electron microscopy. The changes in cytokeratin 55 (CK55), ubiquitin conjugate, nuclear factor kappaB (NFkappaB) p65, NFkappaB p50, inhibitor kappaB alpha, c-myc, tumor necrosis factor alpha, and cytochrome P450 2E1 (CYP2E1) contents were determined by Western blotting using appropriate antibodies. The messenger RNA (mRNA) for CYP2E1, cytokeratin, ubiquitin, hepatocyte growth factor activator, and tissue transglutaminase was quantitated. MBs were present at 5 to 7 days' postfeeding with ethanol, but not with dextrose. They developed in clusters of "empty hepatocytes," where the cytokeratin antibody failed to recognize the typical filament structures seen in normal hepatocytes. MBs were larger and more numerous in the subcapsular region. Northern blots showed that CK55 mRNA was decreased by the ethanol treatment, but protein levels were increased, suggesting a decreased turnover of the cytokeratin. Likewise, the increase in CYP2E1 protein in the face of a lack of an increase in mRNA for CYP2E1 could be explained by a decreased turnover of this cytochrome. This is the first report of MB formation induced by ethanol ingestion in an experimental model.

Simple epithelium keratins are required for maintenance of hepatocyte integrity.

Keratin 8 (K8)-deficient adult mice develop a severe disease of the gastrointestinal tract characterized mainly by colorectal hyperplasia and inflammation. Given that hepatocytes contain K8/K18 heteropolymers only, this animal model was used to assess the contribution of these simple epithelium keratins to hepatocyte structural and functional integrity. Homozygous mutant (HMZ), heterozygous, and wild-type (WT) mice were examined for hepatocyte structural and metabolic features and their survival to partial hepatectomy. Except for the presence of few necrotic foci, no other tissular or cellular alterations were observed in nonhepatectomized HMZ mouse livers; glycogen and lipid peroxidation levels were essentially normal, but a small reduction in bile flow was observed. In response to a single pentobarbital injection, HMZ mice had longer sleeping times than heterozygous and WT mice. After a two-thirds partial hepatectomy under pentobarbital anesthesia, all HMZ mice died within a few hours, whereas those anesthetized with ether survived for 1 to 2 days. One hour after hepatectomy after pentobarbital anesthesia, many hepatocytes contained erythrocytes and large vacuoles in the cytoplasm, which suggests damage at the plasma membrane level in response to a sudden increase in portal blood flow. In line with these findings, an uptake of trypan blue by HMZ but not WT mouse hepatocytes was observed during a 10 ml/minute perfusion via the portal vein with a dye-supplemented buffer. Subsequent cellular dispersion led to viable WT mouse hepatocytes but largely nonviable HMZ mouse hepatocytes. Better viability was obtained at lower perfusion rates. Partially hepatectomized heterozygous mice developed liver steatosis, a condition that was not associated with a change in K8 content but perhaps linked to the presence of the neo gene. Transgenic HMZ mouse rescue experiments with a full-length K8 gene confirmed that the phenotypic alterations observed in partially hepatectomized HMZ mice were caused by the disruption of the K8 gene. Taken together, these findings demonstrate that simple epithelium keratins are essential for the maintenance of hepatocyte structural and functional integrity.

Expression of organ-specific structures and functions in long-term cultures of aggregates from adult rat liver cells.

Freshly isolated hepatocytes, endothelial cells, Kupffer and fat-storing cells from adult rats were found to be able to form spheroidal aggregates within 24 hr when cultured under serum-free and rotatory conditions. The ultrastructure, including intracellular organization and extracellular matrix deposition was investigated in 7-day aggregates by scanning and electron microscopy. The different cell types expressed a histotypic organization and reconstructed their extracellular matrix (fibronectin and laminin) as well as junctional complexes (desmosomes, tight junctions and gap junctions). The aggregates preserved, over a period of at least 7 days, high albumin expression (mRNA) and secretion as well as high secretion of the acute phase protein T-kininogen. Dexamethasone (10(-7) M) increased the tyrosine aminotransferase activity fourfold after a 24-hr exposure. Aggregates cultured in the presence of 10(-7) M dexamethasone showed an increased expression and secretion of albumin concomitantly with a decrease in T-kininogen secretion. Induction of 7-ethoxycoumarin O-deethylase (ECOD) was effective after exposure to 3-methylcholanthrene or Aroclor for 48 hr. Up to a 13-fold increase in (ECOD) activity was found. The results demonstrate that spheroidal cultures of liver cell aggregates obtained under rotatory conditions provide a useful model for studies on the combined cellular interactions between non-parenchymal liver cells and hepatocytes from adult rats.

Mallory body induction in drug-primed mouse liver.

The aim of this study was to determine the various factors that are involved in the induction of Mallory body (MB) formation. A model was developed where MB formation was induced by refeeding either of the drugs griseofulvin or diethyl 1,4-dihydro-1,4,6-trimethyl-3,5-pyridinedicarboxylate (DDC). Mice were fed the drugs for 5 months, followed by withdrawal of the drugs for 1 month (drug-primed livers). The drugs were refed for 1,3,5,7, or 11 days. Early MBs first appeared as small, enlarged aggregates of filaments in the perinuclear or pericanalicular location on the third day of refeeding. Mature MBs appeared on the fifth day of refeeding. MBs reached maximum concentration on day 5 of refeeding. Western blots showed a progressive increase in the cytokeratin proteins (CK49 and CK55) and actin while refeeding the drugs. Liver cell regeneration, as indicated by the percent of proliferating cell nuclear antigen (PCNA)-positive nuclei, increased on the third day of refeeding. However, there was no correlation between the frequency of MBs and the percent of PCNA-positive nuclei. It is concluded that MB formation is not related to the liver cell regeneration response to injury but rather involves a separate regulation pathway. The MBs were heavily ubiquitinated and were associated with increased ubiquitin-protein conjugates as indicated by Western blotting, suggesting that ubiquitinization of cytokeratin protein are involved in the formation of MB aggregation.

Down-regulation of cytokeratin 14 gene expression by the polyoma virus middle T antigen is dependent on c-Src association but independent of full transformation in rat liver nonparenchymal epithelial cells.

Polyoma virus middle T antigen (mT) transforms the T51B cell line and induces the loss of the cytokeratin 8 and 14 pair (CK8/CK14) present in these rat nonparenchymal liver epithelial cells (LECs), because of the selective down-regulation of CK14 gene expression. To identify the initial steps of the mT-induced signaling pathway(s) leading to this inhibition, T51B cells were transfected with vectors encoding the NG59, dl23, and 248M mT mutants, which are known to interact in a differential manner with c-Src, P13-kinase, and Shc. Immunofluorescence microscopy and Northern blot analysis showed a loss of cytokeratins in dl23 or 248M but not in NG59 mT mutant-containing cells. An in vitro kinase assay demonstrated that only the dl23 and 248M mT mutants could associate with c-Src. This c-Src-mediated action of mT on CK14 gene expression was further confirmed by adding the v-src gene product in T51B cells. The assessment of the transforming capacity of the mT mutants demonstrated that the NG59 and dl23 mT mutants were nontransformant, whereas the 248M mT mutant expressed an appreciable transforming activity. These results show that the down-regulation of CK14 gene expression by mT in the LEC line T51B is dependent on the association with the c-Src tyrosine kinase, but interestingly, this c-Src-mediated action of mT can occur in the absence of transformation. Furthermore, when coupled with recent data on the plasticity of LECs, the present findings provide the first essential element in our definition of the signaling pathway(s) that link growth/differentiation events with CK gene regulation in typical simple epithelial cells.

Polyomavirus middle T selective action on cytokeratin 14 gene expression in liver nonparenchymal epithelial cells.

We reported recently that liver nonparenchymal epithelial cells (LECs) constitute a small population of cells scattered throughout biliary structures and the Glisson's capsule, containing the unusual cytokeratin (CK) pair CK8/CK14 (Blouin et al., Differentiation, 1992, 52, 45). The transfection of polyomavirus middle T oncogene (MT) into the LEC line T51B leads to the loss of their CKs, due to a down-regulation of CK14 gene expression (Royal et al., Cell Growth Differ., 1992, 3, 589). In the present work, we examined CK gene expression at both mRNA and protein levels following polyomavirus small T oncogene (ST), MT, or large T oncogene (LT) transfection of T51B cells, MT transfection of rat hepatic cell lines containing different subsets of CKs, and MT transfection of rat keratinocytes. Immunofluorescence staining revealed that MT indeed induced an inhibition of CK14 gene expression and a loss of CK8/CK14 intermediate filaments (IFs) in liver cells, whereas ST and LT had no effect. Moreover, CK14 was the only CK gene whose expression was inhibited in MT-containing hepatic cells, in the sense that the expression of the CK7, CK8, CK18, and CK19 genes was not affected. Two-dimensional SDS-PAGE of the Triton-resistant cytoskeletal proteins and Northern blotting of the CK mRNA content confirmed these findings. The transfer of the MT oncogene into the keratinocytes did not result in the loss of CK5/CK14 IFs nor the inhibition of CK14 gene expression. These results show that the polyomavirus oncogene action on CK gene expression is restricted to an MT effect on CK14 in rat LECs.

Cytokeratin expression, fibrillar organization, and subtle function in liver cells.

Cytokeratins (CKs) constitute a diverse group of intermediate filament (IF) proteins, expressed as pairs in keratinized and nonkeratinizing epithelial cells. Much is known now about the expression, assembly, and function of CKs in keratinized epithelial cells, the main features being the tight coupling between CK pair switch and cell terminal differentiation (protection barrier) and the vital role of CK IFs in cell mechanical integrity. However, the picture about nonkeratinizing epithelia, like the hepatic tissue, remains quite unclear. The liver forms a multicellular system, where parenchymal cells (i.e., hepatocytes) exert diverse metabolic function(s) and nonparenchymal epithelial cells (e.g., biliary epithelial cells) usually serve structural (or accessory) purposes. In terms of differential CK gene expression, the data accumulated so far demonstrated that parenchymal cells can contain as few as one single CK pair, whereas nonparenchymal cells contain more than two CKs, one of them being a representative of those found in epidermis. Moreover, the distribution of the CK IF networks present in the different cell types varies a lot and can often be linked to the cell specialization. However, the function(s) played by these IF proteins in this multicellular tissue remains a major issue. The use of new experimental approaches, largely based on gene transfer technology, indicates that it is quite subtle.

Biliary secretion and actin-cytokeratin filament distribution in rat hepatocytes during phalloidin-induced cholestasis.

The relationship between bile secretion (bile flow, bile acids, phospholipids, and cholesterol) and distribution of actin microfilaments (MFs) and cytokeratin (CK) intermediate filaments (IFs) was examined in hepatocytes of rats injected with a single low dose of phalloidin. This treatment induced a transient cholestasis characterized by a rapid development period (0-90 min postinjection) and a slow recovery period (24 h and 5 days postinjection). No significant changes were observed in bile acid secretion during the 5-day period. The phospholipid output dropped to less than 25% at 90 min and was back to the normal value at 24 h postinjection. In a parallel way, the cholesterol secretion dropped to 30% but came back to only 60% of the control level. Nile Red staining demonstrated a concomitant accumulation of lipids both in the cytoplasm and at the surface membrane. Immunostaining of the actin MFs and CK IFs showed that, in contrast with controls where both cytoskeletal networks were preferentially and uniformly localized at the surface membrane (i.e., sinusoidal, basolateral, and canalicular regions), the toxin treatment led to a major targeting of actin to the pericanalicular region at 24 h and a massive accumulation of well-preserved CK IFs in the cytoplasm at 5 days. Interestingly, this accumulation of CK IFs was not linked to any significant variations in CK isoforms. Together, these data indicate that a selective binding of the toxin to sinusoidal membrane actin at the time of injection triggers a sequence of events that culminate in delayed accumulation of actin MFs at the canalicular pole and of CK IFs in the cytoplasm. Moreover, the reversible perturbation of the bile secretory activity implies a functional adaptation of the hepatocytes that parallels the phalloidin-induced reorganization of both cytoskeleton networks.

Heat shock in vivo induces Mallory body formation in drug primed mouse liver.

Perturbations in keratin intermediate filament organization and Mallory body (MB) formation are associated with alcoholic hepatitis. Inducible heat shock proteins (HSPs) are expressed in a variety of liver diseases including alcoholic liver disease. Therefore, we investigated whether heat shock protein induction can lead to MB formation. Mice were primed by a 5-month feeding of griseofulvin (GF) or diethyl 1,4-dehydro-2,4,6-trimethyl-3,5-pyridinedicarboxylate (DDC) followed by drug withdrawal for 1 month. The animals were then subjected to an in vivo heat shock treatment or sham heat treatment. Liver morphology, HSP expression, liver regeneration (PCNA-labeled nuclei), and MB formation were monitored during a 7-day posttreatment period. Numerous MBs developed in the livers of mice exposed to GF or DDC for 5 months, but very few small MBs remained after 1-month withdrawal of either drug. No MBs were found at Day 1 post heat shock, whereas numerous MBs were observed at Day 7. The frequency of PCNA-labeled nuclei increased during the same period. At Day 1 posttreatment, a variable liver centrilobular necrosis was observed accompanied by a prominent increase in HSP-25 and HSP70 expression, but HSP-90 expression was not increased. In drug-primed mouse liver, a heat shock treatment induces the expression of specific HSPs prior to the formation of MBs, indicating that HSP expression may play a role in the pathogenesis of MB formation. We speculate that this role is through the protein unfolding function of HSP, which leads to the aggregation of the cytokeratins to form MBs as well as to polyubiquitin binding to these proteins in a manner analogous to amyloid formation.

Specialization switch in differentiating embryonic rat liver progenitor cells in response to sodium butyrate.

Embryonic (E) 12 rat liver epithelial cells constitute a population of bipotential progenitor cells which can differentiate along the hepatocyte (Hep) or biliary epithelial cell (BEC) lineage in primary culture. In the present study, E12 cells were seeded on fibronectin-coated substratum and exposed to sodium butyrate (SB) for various exposure times, and the emergence of the Hep or BEC phenotype was monitored by following the variations in albumin production and assessing the appearance of the two surface-exposed markers HES6 and BDS7. Continuous exposure to SB resulted into a major reduction in albumin production and, at Day 9 postseeding, few cells coexpressed BDS7 and albumin. When cells were exposed to SB for 5 days and then cultured for an additional 5 days without SB, they massively express BDS7, but very little HES6. Moreover, the reverse sequence, i.e., 5 days without SB followed by 5 days with it, led to the appearance of many cells expressing both HES6 and BDS7. These results indicate that progenitors committed preferentially along the Hep lineage still have the option to switch to BECs, at a transitional stage that we refer to as a "differentiation window."

Up-regulation of a thymic epithelial ligand after contact with thymocytes.

Thymic medullary epithelial cells of the E-5 line were shown to form in vitro complexes with thymocytes resulting in no apparent modification to the thymocytes participating in the complex, but in tyrosine phosphorylation on a glycoprotein associated with the epithelial adhesion molecule. Because signal transduction from lymphocytes to stromal cells is poorly documented, we examine in this work events which follow epithelial cell activation. Our findings indicate that one chain of the epithelial adhesion molecule (gp23), after complex formation with thymocytes, undergoes a rapid and transient tyrosine kinase-dependent up-regulation.

Gap junctional intercellular communication and connexin expression in normal and SV 40-transformed human liver cells in vitro.

The gap junction intercellular communication (GJIC) capacity of two normal human liver-derived epithelial cell strains and their SV40 large T oncogene-transformed counterparts was examined. In homologous cultures the GJIC capacity of the transformed cells was considerably less than the parental cells. In heterologous cultures, transformed cells appeared to be able to form GJIC channels with normal cells. Only non-transformed cells expressed connexin (cx) 43 gene and cx 26 or cx 32 transcripts were not detectable in any cell strains tested. When GJIC was assayed in the presence of the phorbol ester tumour promoter 12-O-tetradecanoylphorbol-13- acetate (TPA), all four strains showed a marked sensitivity to TPA in inhibitory activity at 1-10 ng/ml. In contrast to a rat liver epithelial cell line, this effect of TPA did not appear to become refractory even after 24 h exposure. These studies demonstrate that GJIC of human liver cells in culture can be decreased by viral oncogene and tumour promoter action. Such disturbance may be an important component of the carcinogenic activity of these agents.

Cytokeratin 14 expression in rat liver cells in culture and localization in vivo.

Rat liver epithelial cells (LECs) are non-parenchymal proliferating cells that readily emerge in primary culture and can be established as cell lines, but their in vivo cell(s) of origin is unclear. We reported recently some evidence indicating that the LEC line, T51B, contains two cytokeratins (CKs) equivalent to human CK8 and CK14 respectively. T51B cells also contain vimentin assembled as a network of intermediate filaments distinct from that of the CKs. In the present study, we examined the expression of CK14 gene in various LEC preparations and a Triton-resistant rat skin cytoskeletal fraction, and then assessed its usefulness as an LEC specific marker in the liver. Northern and Western blot analyses with cDNAs and antibodies for CK8, CK14, CK18 and vimentin confirmed that rat hepatocytes express CK8 and CK18 genes only, whereas T51B cells express CK8, CK14 and vimentin genes in the absence of CK18. CK14 was also present in LECs derived as primary from embryonic-day 12 rat liver and secondary cultures from 4-day-old rat liver. Primary cultures of oval cells isolated from 3'-methyl-4-dimethylaminoazobenzene (3'-Me-DAB) treated rat liver (an enriched source of biliary epithelial cells) contained CK14 mRNAs which were slightly shorter than those in LECs. The analyses of CK5 (the usual partner of CK14) gene expression using specific cDNA and antibody clearly demonstrated its absence in LECs. In situ double immunolocalization analyses by laser scanning confocal microscopy showed that CK14 was not present in hepatocytes (HES6+ cells) and was expressed in some biliary epithelial (BDS7+ cells). CK14-positive cells were also found in the Glisson's capsule. However, CK14-positive cells of the portal region were vimentin negative, whereas those of the Glisson's capsule were vimentin positive. Our results suggest that CK14 gene expression is part of the differentiation program of two types of LECs and that this differential CK14 gene expression can be used as a new means to type LECs in culture and in vivo.

Differential phosphorylation of CK8 and CK18 by 12-O-tetradecanoyl-phorbol-13-acetate in primary cultures of mouse hepatocytes.

The phosphorylation of cytokeratin was investigated in primary cultures of hepatocytes. The two hepatocyte cytokeratins CK8 and CK18 (55,000 and 49,000 M(r) respectively) were phosphorylated, CK8 being more phosphorylated than CK18. Treatment of the hepatocytes with 150 nM 12-O-tetradecanoyl-phorbol-13-acetate (TPA) an activator of protein kinase C induced a transient increase in the level of phosphorylation of CK8 but not CK18. This effect was maximal after 15 min of TPA treatment and was maintained for up to 3 h. After 22 h of treatment with TPA, which down-regulates protein kinase C, CK8 phosphorylation was returned to the basal level. Further addition of TPA to the 22-h treated cells did not cause an increase in CK8 phosphorylation. Indirect immunofluorescence microscopy with a monoclonal antibody to CK8 indicated that while the addition of TPA induced the formation of granular cytokeratin aggregates in some hepatocytes, in most hepatocytes no major changes in the intermediate filament network were observed. Staining for actin showed that actin microfilaments were rapidly reorganized after the treatment and a loss of stress fibres were observed. We propose that CK8 is an in vivo substrate for protein kinase C and that the specific phosphorylation of CK8 plays a role in protein kinase C signal transduction.