ATP-dependent transport of glutathione and glucuronate conjugates from hepatocytes into bile is mediated by a distinct member of the ATP-binding cassette superfamily. We have cloned and sequenced the canalicular isoform of the multidrug resistance protein from rat liver, and termed it cMrp. This membrane glycoprotein is composed of 1541 amino acids with an identity of 47.8% with the human multidrug resistance protein (MRP) and of 41.9% with the yeast cadmium factor (YCF1). The carboxyl-terminal 130 amino acids of the human hepatocyte canalicular isoform of MRP (cMRP) were 80.2% identical with rat cMrp. cMrp was not expressed in the liver of two mutant rat strains, the Eisai hyperbilirubinemic rat and the GY/TR- mutant, which are deficient in the ATP-dependent transport of conjugates across the canalicular membrane. Immunoblotting using an antibody raised against the carboxyl terminus of cMrp detected the glycoprotein of about 190 kDa only in the canalicular membrane from normal liver. Double immunofluorescence and confocal laser scanning microscopy localized cMrp exclusively to the canalicular membrane domain of hepatocytes and demonstrated its loss in the hyperbilirubinemic mutant rat. The results identify cMrp as a canalicular transport protein with a novel sequence and with a function similar to the one of the MRP.
Tumor neovasculature substantially derives from sprouting of existing vessels, whereas the functional contribution of bone marrow-derived progenitors to neovessels remains controversial. We used transgenic mouse models of multistep carcinogenesis to monitor incorporation of bone marrow-derived cells into the neovasculature and to elucidate mechanisms of endothelial precursor cell (EPC) recruitment into the tumor microenvironment. We unequivocally demonstrate integration of bone marrow cells into the tumor vasculature as a late event in carcinogenesis that temporally correlates with VEGF release by the tumor and mobilization of circulating EPC in the periphery. Moreover, we demonstrate a chemokine-dependent mechanism of EPC homing into tumor, whereby neovessels of late-stage tumors release a battery of CC chemokines, which direct CCR2 ؉ and CCR5 ؉ progenitors into the vasculature. Thus, we show that tumor vessels promote their own growth and development in a self-amplifying fashion.cancer ͉ neovascularization
In nontumorigenic mammary epithelial cells (EpH4), transforming growth factor-b (TGFb1) causes cell cycle arrest/apoptosis, but induces epitheliomesenchymal transition (EMT) in Ha-Ras-transformed EpH4 cells (EpRas). EMT is closely correlated with late-stage tumor progression and results in fibroblastic, migratory cells displaying a mesenchymal gene expression program (FibRas). EpRas and FibRas cells showed strongly increased cell substrate adhesion to fibronectin, collagens I/IV and laminin 1. Furthermore, Ras transformation caused enhanced or de-novo expression of the integrin subunits b1, a2 and a3, or a5 and a6, respectively, the latter subunits being even more strongly expressed in FibRas cells. Importantly, polarized EpRas cells expressed integrin subunits b1 and a6 at distinct (apical and lateral) membrane domains, while FibRas cells coexpressed these integrins and a5 at the entire plasma membrane. During EMT, EpRas cells formed an a5b1 complex and deposited its ligand fibronectin into the extracellular matrix. Function-blocking a5 antibodies attenuated migration, and caused massive apoptosis in EpRas cells undergoing TGFb1-induced EMT in collagen gels, but failed to affect EpRas-or FibRas-derived structures. We conclude that functional a5b1 integrin is centrally implicated in EMT induction. Importantly, FibRas cells also failed to deposit the a6b4 ligand laminin 5, suggesting that a6b4 is no longer functional after EMT and replaced by mesenchymal integrins such as a5b1.
The anucleate prismoid fiber cells of the eye lens are densely packed to form a tissue in which the plasma membranes and their associated cytoplasmic coat form a single giant cell-cell adhesive complex, the cortex adhaerens. Using biochemical and immunoprecipitation methods in various species (cow, pig, rat), in combination with immunolocalization microscopy, we have identified two different major kinds of cortical complex. In one, the transmembrane glycoproteins N-cadherin and cadherin-11 [which also occur in heterotypic (`mixed') complexes] are associated with α- and β-catenin, plakoglobin (proportions variable among species), p120ctn and vinculin. The other complex contains ezrin, periplakin, periaxin and desmoyokin (and so is called the EPPD complex), usually together with moesin, spectrin(s) and plectin. In sections through lens fiber tissue, the short sides of the lens fiber hexagons appear to be enriched in the cadherin-based complexes, whereas the EPPD complexes also occur on the long sides. Moreover, high resolution double-label fluorescence microscopy has revealed, on the short sides, a finer, almost regular mosaicism of blocks comprising the cadherin-based, catenin-containing complexes, alternating with patches formed by the EPPD complexes. The latter, a new type of junctional plaque ensemble of proteins hitherto known only from certain other cell types, must be added to the list of major lens cortex proteins. We here discuss its possible functional importance for the maintenance of lens structure and functions, notably clear and sharp vision.
Recent studies on the subcellular distribution of cytoplasmic plaque proteins of intercellular junctions have revealed that a number of such proteins can also occur in the cyto-and the nucleoplasm. This occurrence in different, and distant locations suggest that some plaque proteins play roles in cytoplasmic and nuclear processes in addition to their involvement in cell-cell adhesive interactions. Plakophilin (PKP) 3, a member of the arm-repeat family of proteins, occurs, in a diversity of cell types, both as an architectural component in plaques of desmosomes and dispersed in cytoplasmic particles. In immuno-selection experiments using PKP3-specific antibodies, we have identified by mass spectrometric analysis the following RNA-binding proteins: Poly (A) binding protein (PABPC1), fragile-X-related protein (FXR1), and ras-GAP-SH3-binding protein (G3BP). Moreover, the RNA-binding proteins codistributed after sucrose gradient centrifugation in PKP3-containing fractions corresponding to 25-35 S and 45-55 S. When cells are exposed to environmental stress (e.g., heat shock or oxidative stress) proteins FXR1, G3BP, and PABPC1 are found, together with PKP3 or PKP1, in "stress granules" known to accumulate stalled translation initiation complexes. Moreover, the protein eIF-4E and the ribosomal protein S6 are also detected in PKP3 particles. Our results show that cytoplasmic PKP3 is constitutively associated with RNA-binding proteins and indicate an involvement in processes of translation and RNA metabolism. INTRODUCTIONOver the past decade, several studies on the subcellular distribution of the plaque proteins of adhering junctions have revealed that a number of such proteins are not only constituents of cell-cell contact structures but also found dispersed in the cytoplasm and nucleus. This dual location suggests that in addition to establishing and maintaining cell adhesive functions these proteins may also play roles in nuclear and ribonucleoprotein processing mechanisms. Such proteins include members of the arm-repeat family, which are characterized by variable numbers of an ϳ42-amino acid motif (Peifer et al., 1994). Among these nonjunctional functions the signaling roles of -catenin and protein p120 have been rather well characterized (for reviews, see Anastasiadis and Reynolds, 2000;Huelsken and Birchmeier, 2001;Nelson and Nusse, 2004). For example, -catenin is a key player in the Wnt pathway, directly mediating downstream events through transactivation of transcription factors of the Lef1/ TCF family to coordinate the activation of gene targets (Clevers and van de Wetering, 1997). Additional more recent evidence indicates that protein p120 also regulates cadherin turnover at the cell surface, thereby controlling the amount of cadherin available for cell adhesion (Kowalczyk and Reynolds, 2004;Reynolds and Roczniak-Ferguson, 2004) Less is known on the functions of the plakophilins (PKPs), which are characteristic plaque proteins of desmosomes and also occur nearly ubiquitously and constitutively in the cytoplasm...
The Dubin-Johnson syndrome is an inherited disorder characterized by conjugated hyperbilirubinemia. The deficient hepatobiliary transport of anionic conjugates is caused by the absence of a functional multidrug-resistance protein 2 (MRP2, symbol ABCC2) from the apical (canalicular) membrane of hepatocytes. Mechanisms underlying this deficiency may include rapid degradation of mutated MRP2 messenger RNA (mRNA) or impaired MRP2 protein maturation and trafficking. We investigated the consequences of the mutation MRP2Delta(R,M), which leads to the loss of 2 amino acids from the second ATP-binding domain of MRP2. The MRP2Delta(R,M) mutation is associated with the absence of the MRP2 glycoprotein from the apical membrane of hepatocytes. Transfection of mutated MRP2 complementary DNA (cDNA) led to an MRP2Delta(R,M) protein that was only core glycosylated, sensitive to endoglycosidase H digestion, and located in the endoplasmic reticulum (ER) of transfected HEK293 and HepG2 cells. This indicated that deletion of Arg1392 and Met1393 leads to impaired maturation and trafficking of the protein from the ER to the Golgi complex. Inhibition of proteasome function resulted in a paranuclear accumulation of the MRP2Delta(R,M) protein, suggesting that proteasomes are involved in the degradation of the mutant protein. This is the first mutation in Dubin-Johnson syndrome shown to cause deficient MRP2 maturation and impaired sorting of this glycoprotein to the apical membrane.
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