The role of plasma membrane in bioreduction of two tetrazolium salts, MTT, and CTC

Despite widespread use of various tetrazolium assays, the mechanisms of bioreduction of these compounds have not been fully elucidated. We investigated the capacity of tetrazolium salts to penetrate through intact cell plasma membranes. 5-cyano-2,3-ditolyl tetrazolium chloride (CTC) and 3-(4,5-dimethylthiazol-2-yl)-2,5 diphenyltetrazolium bromide (MTT) tetrazolium salts appear to represent examples of species that are reduced by different mechanisms. We provide evidence suggesting that MTT readily crosses intact plasma membranes and is reduced intracellularly. MTT appears to be reduced by both plasma membrane and intracellular reductases; reducing cells are not damaged and remain metabolically active for at least 45 min. In contrast, CTC remains extracellular with respect to viable cells and thus requires plasma membrane permeable electron carrier to be reduced efficiently. However, reduction of CTC in the presence of an electron carrier inflicts damage on plasma membranes. The intracellular vs extracellular sites of reduction of tetrazolium salts were established on the basis of deposition of formazans. Crystals of formazan were detected using fluorescence or backscattered light confocal laser microscopy. We postulate that the capacity of a tetrazolium salt to cross intact plasma membranes constitutes an important experimental variable which needs to be controlled in order to correctly interpret the outcome of tetrazolium assays designed to measure cellular production of oxygen radicals, activity of mitochondrial, cytosolic, or outer membrane reductases, etc.     

Novel membranes and surface modification able to activate specific cellular responses

The design of new polymeric biomaterials together with new strategies to modify membrane surface are crucial to optimise cell-biomaterial interactions in vivo and in vitro biohybrid systems. In this study we report on the novel semipermeable membranes synthesised from a polymeric blend of modified polyetheretherketone and polyurethane able to support the long-term maintenance and differentiation of human liver cells and on the surface modification of polyethersulfone membranes by plasma polymerisation of acrylic acid monomers and by immobilization of arginine-glycine-aspartic acid (RGD) peptide through a hydrophilic "spacer arm" molecule. The performance of the modified and unmodified membranes was tested by evaluation of the liver function expression of primary human hepatocytes in terms of albumin production, protein secretion and drug biotransformation.     

Multiple proteins with single activities or a single protein with multiple activities: the conundrum of cell surface NADH oxidoreductases

Reduction of the cell-impermeable tetrazolium salt WST-1 has been used to characterise two plasma membrane NADH oxidoreductase activities in human cells. The trans activity, measured with WST-1 and the intermediate electron acceptor mPMS, utilises reducing equivalents from intracellular sources, while the surface activity, measured with WST-1 and extracellular NADH, is independent of intracellular metabolism. Whether these two activities involve distinct proteins or are inherent to a single protein is unclear. In this work, we have attempted to address this question by examining the relationship between the trans and surface WST-1-reducing activities and a third well-characterised family of cell surface oxidases, the ECTO-NOX proteins. Using blue native-polyacrylamide gel electrophoresis, we have identified a complex in the plasma membranes of human 143B osteosarcoma cells responsible for the NADH-dependent reduction of WST-1. The dye-reducing activity of the 300 kDa complex was attributed to a 70 kDa NADH oxidoreductase activity that cross-reacted with antisera against the ECTO-NOX protein CNOX. Differences in enzyme activities and inhibitor profiles between the WST-1-reducing NADH oxidoreductase enzyme in the presence of NADH or mPMS and the ECTO-NOX family are reconciled in terms of the different purification methods and assay systems used to study these proteins.     

Neutrophil serine proteinases activate human nonepithelial cells to produce inflammatory cytokines through protease-activated receptor 2

Protease-activated receptors (PARs) compose a family of G protein-coupled receptors activated by proteolysis with exposure of their tethered ligand. Recently, we reported that a neutrophil-derived serine proteinase, proteinase 3 (PR3), activated human oral epithelial cells through PAR-2. The present study examined whether other neutrophil serine proteinases, human leukocyte elastase (HLE), and cathepsin G (Cat G) activate nonepithelial cells, human gingival fibroblasts (HGF). HLE and Cat G as well as PR3 activated HGF to produce IL-8 and monocyte chemoattractant protein 1. Human oral epithelial cells but not HGF express mRNA and protein of secretory leukocyte protease inhibitor, an inhibitor of HLE and Cat G, and recombinant secretory leukocyte protease inhibitor clearly inhibited the activation of HGF induced by HLE and Cat G but not by PR3. HGF express PAR-1 and PAR-2 mRNA in the cells and the proteins on the cell surface. HLE and Cat G cleaved the peptide corresponding to the N terminus of PAR-2 with exposure of its tethered ligand. Treatment with trypsin, an agonist for PAR-2, and a synthetic PAR-2 agonist peptide induced intracellular Ca(2+) mobilization and rendered cells refractory to subsequent stimulation with HLE and Cat G. The production of cytokine induced by HLE and Cat G and the PAR-2 agonist peptide was completely abolished by inhibition of phospholipase C. These findings suggest that neutrophil serine proteinases have equal ability to activate human nonepithelial cells through PAR-2 to produce inflammatory cytokines and may control a number of inflammatory processes such as periodontitis.     

Light microscopic localization of glycosyltransferase activities in cells and tissues

We describe an assay for light microscopic visualization of specific glycosyltransferases on tissue sections or on cells. The assay uses a sequence of enzyme reactions that yields two moles of NADH for each mole of the uridine-5'-diphosphate (UDP) released during transfer of a monosaccharide from a UDP sugar to an acceptor. When diaphorase and tetrazolium salts are present in the incubation mixture, the tetrazolium salts are reduced to colored diformazans, which precipitate at the sites of glycosyltransferase activity. The validity of the assay was established by applying the technique to spermatozoa and liver, in which some glycosyltransferases have previously been localized. When suspensions of mouse spermatozoa were assayed for galactosyltransferase (GalTase) activity, diformazan precipitates appeared on the plasma membranes overlying the anterior heads of the spermatozoa, in agreement with immunochemical localizations. In mouse liver slices assayed with bilirubin as acceptor for glucuronyltransferase (GluTase) activity, dense diformazan deposits appeared on the hepatocytes but not on endothelial cells, also in agreement with immunochemical data. In the absence of acceptor or UDP sugar donor, diformazan deposits were minimal and random in all tissues tested. The assay's versatility was tested by incubating tissues with different sugar donors and acceptors to localize other sites of transferase activity. In mouse frozen liver sections, GalTase activity occurred in both hepatocytes and endothelial cells; in sections of rat submaxillary glands, GalTase activity was detected in mast cells. In liver sections, GlcuTase activity with o-aminophenol as acceptor was located primarily on the endothelial cells. With the appropriate sugar donor and acceptor, this assay should detect any transferase, other than the glucosyltransferases, that utilizes UDP sugars.     

Plasma membranes contain half the phospholipid and 90% of the cholesterol and sphingomyelin in cultured human fibroblasts

The literature suggests that cholesterol and sphingomyelin might be essentially confined to plasma membranes in mammalian cells; however, this premise has thus far escaped a direct test. We explored the issue in three ways. First, we fractionated whole homogenates of cultured human fibroblasts by equilibrium sucrose density gradient centrifugation. We found that the profiles of cholesterol and sphingomyelin were indistinguishable from those of two plasma membrane markers, 5' nucleotidase and [3H]galactose, which was conjugated to the surface of intact cells from an exogenous donor by galactosyltransferase. Second, we determined the relative surface areas of intact cells from their uptake of 1-(4-trimethyl-amino)phenyl-6-phenylhexa-1,3,5-triene, a cationic fluorescent dye which partitions into but does not cross plasma membranes. Relative to human red cell ghosts, the apparent surface area of the fibroblasts was 17,500 microns2/cell while for canine hepatocytes, the value was 11,500 microns2/cell. The relative ratios of cell cholesterol to dye binding (hence, surface area) were quite similar in ghosts, fibroblasts, and liver cells; namely 1.0, 1.12, and 0.67, respectively. Finally, we found that the specific ratios of both cholesterol and sphingomyelin to 5' nucleotidase were only 10% less in gradient-purified plasma membranes than in whole homogenates. Similar results were obtained using an entirely different method of purification: two-phase aqueous partition. The cholesterol and sphingomyelin in fractions rich in other membranes was closely proportional to their 5' nucleotidase content, suggesting that the presence of these lipids reflected contamination by plasma membrane fragments. The 5' nucleotidase/phospholipid ratio in the purified plasma membrane fraction was roughly twice that in whole cells. We conclude that the compartment marked by 5' nucleotidase in cultured human fibroblasts contains approximately 90% of the two named lipids and half the cell phospholipid phosphorus.     

Characterization of the endogenous GIT1-betaPIX complex, and identification of its association to membranes

G protein-coupled receptor kinase interactors (GITs) are adaptor proteins with ADP-ribosylating factor--GTPase-activating protein (ARF-GAP) activity that form complexes with the p21-activated kinase-interacting exchange factor (PIX) guanine nucleotide exchanging factors for Rac and Cdc42. In this study we have characterized the endogenous GIT1/p95-APP1/Cat1 (GIT1)- PIX complexes in neuronal and non-neuronal cells. In COS7 cells, immunocytochemical analysis shows the localization of endogenous GIT1 in the perinuclear region of the cell, as well as at the cell periphery, where GIT1 co-localizes with filamentous actin. The perinuclear localization of endogenous GIT1 was confirmed in avian fibroblasts. In COS7 cells, immunoprecipitation and microsequencing experiments with either anti-GIT1 or anti-betaPIX antibodies unequivocally show that betaPIX is uniquely associated with GIT1 in lysates from these cells, while GIT2/PKL/p95-APP2/Cat2 (GIT2) is undetectable in the endogenous complexes. Moreover, this analysis demonstrates that betaPIX is the limiting factor for the formation of the endogenous complexes, since a small fraction of GIT1 can be co-immunoprecipitated with most betaPIX from these cells. Saponin treatment of unfixed cells indicates that betaPIX-bound GIT1 is preferentially retained in the saponin-resistant fraction when compared to betaPIX-free GIT1. Moreover, analysis by tissue fractionation shows that a significant fraction of the endogenous GIT1-betaPIX complex is firmly associated to membranes from brain homogenates. Our findings show the specific localization of the complex at intracellular membranes, and indicate a correlation between the association of GIT1 to betaPIX, and the localization of the endogenous complex at membranes.     

Human liver plasma membranes contain receptors for the hepatitis B virus pre-S1 region and, via polymerized human serum albumin, for the pre-S2 region.

Hepatitis B virus particles contain three related viral envelope proteins, the small, middle, and large S (surface) proteins. All three proteins contain the small S amino acid sequence at their carboxyl terminus. It is not clear which of these S proteins functions as the viral attachment protein, binding to a target cell receptor and initiating infection. In this report, recombinant hepatitis B surface antigen (rHBsAg) particles, which contain only virus envelope proteins, were radioactively labeled, and their attachment to human liver membranes was examined. Only the rHBsAg particles containing the large S protein were capable of directly attaching to liver plasma membranes. The attachment was saturable and could be prevented by competition with unlabeled particles or by a monoclonal antibody specific for the large S protein. In the presence of polymerized human serum albumin, both large and middle S protein-containing rHBsAg particles were capable of attaching to the liver plasma membranes. Small S protein-containing rHBsAg particles were not able to attach even in the presence of polymerized human serum albumin. These results indicate that the large S protein may be the viral attachment protein for hepatocytes, binding directly to liver plasma membranes by its unique amino-terminal (pre-S1) sequence. These results also indicate that polymerized human serum albumin or a similar molecule could act as an intermediate receptor, attaching to liver plasma membranes and to the amino acid sequence (pre-S2) shared by the middle and large S proteins but not contained in the small S protein.     

Correlation between plasma membrane surface area and transferrin secretion rate in isolated hepatocytes

It is generally considered that in exocytosis the size of the secreting cells does not increase when the membranes of exocytosis vesicles fuse with the plasma membrane. As the factors involved in the regulation of this phenomenon are poorly understood, we thought it worthwhile to investigate the relationship between the plasma membrane surface area and secretory activity. Isolated rat hepatocytes were prepared by liver collagenase perfusion. Secretion of the plasma protein, transferrin (Tf) was detected at the single cell level with specific anti-rat transferrin antibodies using the reverse hemolytic plaque test. Hepatocyte surface and hemolytic ring surface areas were calculated from diameters of hepatocyte and hemolytic plaque measured after 5h of incubation. A highly significant correlation was established between the plaque-forming hepatocyte surface areas and the corresponding hemolytic surface areas. This result was confirmed using an automatic image analysis method. Two-month-old rats were compared to 4-month-old rats. We observed that the ratio of the quantity of transferrin secreted by hepatocytes to the hepatocyte surface area was constant for a given incubation time, whatever the size of the hepatocytes. These results suggest that the plasma membrane surface area of hepatocytes may constitute a limiting factor in Tf secretion.     

Transport of acid phosphatase to lysosomes does not involve passage through the cell surface

In foregoing studies, we reported that LGP107, a major lysosomal membrane glycoprotein in the rat liver, distributes in and circulates continuously throughout the endocytic membrane system (endosomes, lysosomes and plasma membrane), in hepatocytes (1,2). In the present study we examined whether acid phosphatase (APase), an enzyme that is transported to lysosomes as a transmembrane protein, passes through the cell surface during intracellular transport, because transport of newly synthesized APase to lysosomes involves the passage of endosomes containing a ligand which is internalized via receptors on the cell surface and is finally dispatched to lysosomes for degradation (3). When localization of APase in rat hepatocytes was investigated by immunoelectron microscopy, APase was found to be localized in lysosomes and endosomes, but not in coated pits on the cell surface, which are positive for LGP107, and from which antibodies for LGP107 are internalized. Further, unlike LGP107, newly synthesized APase was not detected in plasma membranes isolated from livers of rats given [35S]methionine, and when cultured hepatocytes were exposed to 125I-labeled anti APase IgG at 37 degrees C, there was no transfer of the antibody to lysosomes even after 24 h incubation. Therefore, these results indicate that intracellular movement of APase does not involve cell surface passage in rat hepatocytes, and clearly differs from the recent report that human APase is transported to lysosomes via the cell surface in BHK cells transfected with its cDNA (4).     

Spheroid formation and functional restoration of human fetal hepatocytes on poly-amino acid-coated dishes after serial proliferation

Primary human fetal hepatocytes proliferated in monolayer culture up to the 9th passage. During proliferation, the cells changed their morphology from a fibroblast-like shape after inoculation to an epithelia-like polygonal shape after they reached confluence. The proliferation was associated with the loss of ammonia detoxification capacity, which is essential for the function of bioartificial liver. The cells formed spheroids on a poly-glutamic acid- or poly-aspartic acid-coated polystyrene dish that had a negatively charged surface at neutral pH. However, the cells did not form spheroids on a poly-lysine- or poly-arginine-coated dish that had a positively charged surface, which is reportedly suitable to form spheroids for adult hepatocytes. The activity of cytochrome P450 (CYP 1A1, CYP1A2) of the cells in spheroid culture was about twice as high as that of the cells in monolayer culture. The ammonia detoxification activity of the cells was restored in spheroid culture by treatment with 2% dimethylsulfoxide. These results suggest that the conditions for human fetal hepatocytes to form spheroids are different from that for adult hepatocytes, and the use of poly-glutamic acid or poly-aspartic acid coating may improve spheroid culture of proliferative human fetal hepatocytes. This revised version was published online in July 2006 with corrections to the Cover Date.     

Identification of a novel glycoprotein (AGp110) involved in interactions of rat liver parenchymal cells with fibronectin

We have identified an integral membrane glycoprotein in rat liver that mediates adhesion of cultured hepatocytes on fibronectin substrata. The protein was isolated by affinity chromatography of detergent extracts on wheat germ lectin-Agarose followed by chromatography of the WGA binding fraction on fibronectin-Sepharose. The glycoprotein (AGp110), eluted at high salt concentrations from the fibronectin column, has a molecular mass of 110 kD and a pI of 4.2. Binding of immobilized AGp110 to soluble rat plasma fibronectin required Ca2+ ions but was not inhibited by RGD peptides. Fab' fragments of immunoglobulins raised in rabbits against AGp110 reversed the spreading of primary hepatocytes attached onto fibronectin-coated substrata, but had no effect on cells spread on type IV collagen or laminin substrata. The effect of the antiserum on cell spreading was reversible. AGp110 was detected by immunofluorescence around the periphery of the ventral surface of substratum attached hepatocytes, and scattered on the dorsal surface. Immunohistochemical evidence and Western blotting of fractionated liver plasma membranes indicated a bile canalicular (apical) localization of AGp110 in the liver parenchyma. Expression of AGp110 is tissue specific: it was found mainly in liver, kidney, pancreas, and small intestine but was not detected in stomach, skeletal muscle, heart, and large intestine. AGp110 could be labeled by lactoperoxidase-catalyzed surface iodination of intact liver cells and, after phase partitioning of liver plasma membranes with the detergent Triton X-114, it was preferentially distributed in the hydrophobic phase. Treatment with glycosidases indicated extensive sialic acid substitution in at least 10 O-linked carbohydrate chains and 1-2 N-linked glycans. Immunological comparisons suggest that AGp110, the integrin fibronectin receptor and dipeptidyl peptidase IV, an enzyme involved in fibronectin-mediated adhesion of hepatocytes on collagen, are distinct proteins.     

Interaction of heme and heme-hemopexin with an extracellular oxidant system used to measure cell growth-associated plasma membrane electron transport

Since redox active metals are often transported across membranes into cells in the reduced state, we have investigated whether exogenous ferri-heme or heme bound to hemopexin (HPX), which delivers heme to cells via receptor-mediated endocytosis, interact with a cell growth-associated plasma membrane electron transport (PMET) pathway. PMET reduces the cell-impermeable tetrazolium salt, WST-1, in the presence of the mandatory low potential intermediate electron acceptor, mPMS. In human promyelocytic (HL60) cells, protoheme (iron protoporphyrin IX; 2,4-vinyl), mesoheme (2,4-ethyl) and deuteroheme (2,4-H) inhibited reduction of WST-1/mPMS in a saturable manner supporting interaction with a finite number of high affinity acceptor sites (Kd 221 nM for naturally occurring protoheme). A requirement for the redox-active iron was shown using gallium-protoporphyrin IX (PPIX) and tin-PPIX. Heme-hemopexin, but not apo-hemopexin, also inhibited WST-1 reduction, and copper was required. Importantly, since neither heme nor heme-hemopexin replace mPMS as an intermediate electron acceptor and since inhibition of WST-1/mPMS reduction requires living cells, the experimental evidence supports the view that heme and heme-hemopexin interact with electrons from PMET. We therefore propose that heme and heme-hemopexin are natural substrates for this growth-associated electron transfer across the plasma membrane.     

Tumor necrosis factor-alpha-associated lysosomal permeabilization is cathepsin B dependent

Cathepsin B (Cat B) is released from lysososomes during tumor necrosis factor-alpha (TNF-alpha) cytotoxic signaling in hepatocytes and contributes to cell death. Sphingosine has recently been implicated in lysosomal permeabilization and is increased in the liver by TNF-alpha. Thus the aims of this study were to examine the mechanisms involved in TNF-alpha-associated lysosomal permeabilization, especially the role of sphingosine. Confocal microscopy demonstrated Cat B-green fluorescent protein and LysoTracker Red were both released from lysosomes after treatment of McNtcp.24 cells with TNF-alpha/actinomycin D, a finding compatible with lysosomal destabilization. In contrast, endosomes labeled with Texas Red dextran remained intact, suggesting lysosomes were specifically targeted for permeabilization. LysoTracker Red was released from lysosomes in hepatocytes treated with TNF-alpha or sphingosine in Cat B(+/+) but not Cat B(-/-) hepatocytes, as assessed by a fluorescence-based assay. With the use of a calcein release assay in isolated lysosomes, sphingosine permeabilized liver lysosomes isolated from Cat B(+/+) but not Cat B(-/-) liver. C(6) ceramide did not permeabilize lysosomes. In conclusion, these data implicate a sphingosine-Cat B interaction inducing lysosomal destabilization during TNF-alpha cytotoxic signaling.     

Bile acid binding proteins in hepatocellular membranes of newborn and adult rats. Identification of transport proteins with azidobenzamidotauro[14C]cholate ([14C]ABATC)

Neonatal hepatocytes are less active in uptake of bile acids than are mature hepatocytes. This phenomenon has been further investigated by transport studies with azidobenzamidotaurocholate (ABATC). Taurocholate, cholate and the photolabile ABATC were taken up by liver cells of adult rats by a sodium-dependent and by an additional sodium-independent mechanism. In the dark, ABATC inhibited the uptake of taurocholate and cholate. Taurocholate decreased the transport of ABATC in a competitive manner, both in the presence and absence of sodium. In neonatal hepatocytes the Vmax for taurocholate and for ABATC was similar but was lower than in mature liver cells. In contrast, the Km was similar for neonatal and mature hepatocytes. For identification of binding proteins in both kinds of cells ABATC was photolysed after preincubation with isolated hepatocytes. Under our experimental conditions (single ultraviolet flash) about 80% of the azido groups was converted to nitrene. The covalently binding nitrene derivative inhibited bile salt transport irreversibly. Photolabeling of intact hepatocytes or of isolated plasma membranes with ABATC resulted in radioindication of membrane proteins with 67, 60, 54, 50 and 43 kDa in mature plasma membranes but of proteins with masses of 67, 54, 43 and 37 kDa in neonatal basolateral membranes. The 50 kDa protein in largely lacking in membranes of 9-day-old rats. The process of photolabeling itself was sodium-independent when isolated cells were treated with ABATC. In contrast, the degree of labeling of intact hepatocytes was markedly reduced in the absence of sodium and chloride. 100-fold molar excess of taurocholate, benzamidotaurocholate (BATC), phalloidin or cyclosomatostatin protected isolated plasma membranes against coupling of ABATC. Photolabeling of hepatoma cells known to be deficient in bile salt transport did not result in radiomodification of membrane proteins.     

ORP10, a cholesterol binding protein associated with microtubules, regulates apolipoprotein B-100 secretion

ORP10/OSBPL10 is a member of the oxysterol-binding protein family, and genetic variation in OSBPL10 is associated with dyslipidemias and peripheral artery disease. In this study we investigated the ligand binding properties of ORP10 in vitro as well as its localization and function in human HuH7 hepatocytes. The pleckstrin homology (PH) domain of ORP10 selectively interacts with phosphatidylinositol-4-phosphate, while the C-terminal ligand binding domain binds cholesterol and several acidic phospholipids. Full-length ORP10 decorates microtubules (MT), while the ORP10 N-terminal fragment (aa 1-318) localizes at Golgi membranes. Removal of the C-terminal aa 712-764 of ORP10 containing a predicted coiled-coil segment abolishes the MT association, but allows partial Golgi targeting. A PH domain-GFP fusion protein is distributed mainly in the cytosol and the plasma membrane, indicating that the Golgi affinity of ORP10 involves other determinants in addition to the PH domain. HuH7 cells expressing ORP10-specific shRNA display increased accumulation of apolipoprotein B-100 (apoB-100), but not of albumin, in culture medium, and contain reduced levels of intracellular apoB-100. Pulse-chase analysis of cellular [(35)S]apoB-100 demonstrates enhanced apoB-100 secretion by cells expressing ORP10-specific shRNA. The apoB-100 secretion phenotype is replicated in HepG2 cells transduced with the ORP10 shRNA lentiviruses. As a conclusion, the present study dissects the determinants of ORP10 association with MT and the Golgi complex and provides evidence for a specific role of this protein in β-lipoprotein secretion by human hepatocytes.     

Interaction of heme and heme-hemopexin with an extracellular oxidant system used to measure cell growth-associated plasma membrane electron transport

Since redox active metals are often transported across membranes into cells in the reduced state, we have investigated whether exogenous ferri-heme or heme bound to hemopexin (HPX), which delivers heme to cells via receptor-mediated endocytosis, interact with a cell growth-associated plasma membrane electron transport (PMET) pathway. PMET reduces the cell-impermeable tetrazolium salt, WST-1, in the presence of the mandatory low potential intermediate electron acceptor, mPMS. In human promyelocytic (HL60) cells, protoheme (iron protoporphyrin IX; 2,4-vinyl), mesoheme (2,4-ethyl) and deuteroheme (2,4-H) inhibited reduction of WST-1/mPMS in a saturable manner supporting interaction with a finite number of high affinity acceptor sites (Kd 221 nM for naturally occurring protoheme). A requirement for the redox-active iron was shown using gallium-protoporphyrin IX (PPIX) and tin-PPIX. Heme-hemopexin, but not apo-hemopexin, also inhibited WST-1 reduction, and copper was required. Importantly, since neither heme nor heme-hemopexin replace mPMS as an intermediate electron acceptor and since inhibition of WST-1/mPMS reduction requires living cells, the experimental evidence supports the view that heme and heme-hemopexin interact with electrons from PMET. We therefore propose that heme and heme-hemopexin are natural substrates for this growth-associated electron transfer across the plasma membrane.     

Endothelial signals modulate hepatocyte apicobasal polarization in zebrafish

Emerging evidence indicates that paracrine signals from endothelial cells play a role in tissue differentiation and organ formation [1-3]. Here, we identify a novel role for endothelial cells in modulating hepatocyte polarization during liver organogenesis. We find that in zebrafish, the apical domain of the hepatocytes predicts the location of the intrahepatic biliary network. The refinement of hepatocyte polarization coincides with the invasion of endothelial cells into the liver, and these endothelial cells migrate along the maturing basal surface of the hepatocytes. Using genetic, pharmacological, and transplantation experiments, we provide evidence that endothelial cells influence the polarization of the adjacent hepatocytes. This influence of endothelial cells on hepatocytes is mediated at least in part by the cell-surface protein Heart of glass and contributes to the establishment of coordinately aligned hepatocyte apical membranes and evenly spaced intrahepatic conduits.     

Separate and shared lysosomal transport of branched and aromatic dipolar amino acids

Transport systems analogous to the T and L carriers for aromatic and bulky dipolar amino acids in plasma membranes have been characterized in the membranes of intact lysosomes isolated from human fetal skin fibroblasts. While system L appears ubiquitous in plasma membranes, system T has previously been discriminated only in the plasmalemma of human red blood cells and freshly isolated rat hepatocytes. Our findings with the lysosomal systems, provisionally designated t and l, reveal both shared and dissimilar properties with the plasma membrane systems. These properties include a lack of dependency on extralysosomal Na+, differential sensitivities to the classical system L analog, 2-aminobicyclo[2.2.1]heptane-2-carboxylic acid (BCH), and the system T analog, D-tryptophan, as well as susceptibility to thiol modification at the membrane by reactivity with N-ethylmaleimide. A transport system in lysosomes from the FRTL-5 rat thyroid cell line has been described by Bernar et al. ((1986) J. Biol. Chem. 261, 17107-17112) resembles a composite of both carrier systems reported in this work.     

Monoclonal antibodies to the human laminin receptor recognize structurally distinct sites

Laminin, a glycoprotein of basement membranes, binds to a specific receptor on the surface of neoplastic and non-neoplastic cells. The laminin receptor purified from human breast carcinoma plasma membranes was used as an antigen to generate two types of monoclonal antibodies (mAbs). Both types of mAbs bind to (a) the purified receptor coated on a solid phase; (b) isolated breast carcinoma plasma membranes; and (c) the surface of cultured MCF-7 human breast carcinoma cells by immunohistology. Using immunoblotting, both types of mAbs recognize a single 67 000 Dalton protein among all the proteins extracted from breast carcinoma plasma membranes. The mAbs differed in their ability to block binding of laminin to the plasma membrane receptor. Antibody LR1 inhibited virtually 100% of the specific binding of laminin to both the isolated human breast carcinoma plasma membranes or the living MCF-7 cells. In contrast, antibody LR2 had no effect on laminin binding under identical conditions. Thus, the two types of mAbs may recognize structurally distinct sites on the laminin receptor. These mAbs should be useful to dissect the biology and the molecular genetics of the laminin receptor.