The ERM protein, ezrin, regulates neutrophil transmigration by modulating the apical localization of MRP2 in response to the SipA effector protein during Salmonella Typhimurium infection

In human disease induced by Salmonella enterica serovar Typhimurium (S. Typhimurium), transepithelial migration of neutrophils rapidly follows attachment of the bacteria to the epithelial apical membrane. We have previously shown that during S. Typhimurium infection the multidrug resistance-associated protein 2 (MRP2) is highly expressed at the apical surface of the intestinal epithelia, and that it functions as an efflux pump for the potent neutrophil chemoattractant hepoxilin A(3) . However, the molecular mechanisms regulating its apical localization during active states of inflammation remain unknown. Thus, our objective was to determine the mechanistic basis for the translocation of MRP2 to the apical surface of intestinal epithelial cells during S. Typhimurium infection. We show that suppression of ezrin, through either RNAi or truncation of the C-terminus, results not only in a decrease in S. Typhimurium-induced neutrophil transmigration but also significantly attenuates the apical membrane expression of MRP2 during Salmonella infection. In addition, we determined that S. Typhimurium induces the activation of ezrin via a PKC-α-dependent pathway and that ezrin activation is coupled to apical localization of MRP2. Based on these results we propose that activation of ezrin is required for the apical localization of MRP2 during S. Typhimurium infection.     

PALS1 specifies the localization of ezrin to the apical membrane of gastric parietal cells

The ERM (ezrin/radixin/moesin) proteins provide a regulated linkage between membrane proteins and the cortical cytoskeleton and also participate in signal transduction pathways. Ezrin is localized to the apical membrane of parietal cells and couples the protein kinase A activation cascade to regulated HCl secretion in gastric parietal cells. Here, we show that the integrity of ezrin is essential for parietal cell activation and provide the first evidence that ezrin interacts with PALS1, an evolutionarily conserved PDZ and SH3 domain-containing protein. Our biochemical study verifies that ezrin binds to PALS1 via its N terminus and is co-localized with PALS1 to the apical membrane of gastric parietal cells. Furthermore, our study shows that PALS1 is essential for the apical localization of ezrin, as either suppression of PALS1 protein accumulation or deletion of the PALS1-binding domain of ezrin eliminated the apical localization of ezrin. Finally, our study demonstrates the essential role of ezrin-PALS1 interaction in the apical membrane remodeling associated with parietal cell secretion. Taken together, these results define a novel molecular mechanism linking ezrin to the conserved apical polarity complexes and their roles in polarized epithelial secretion of gastric parietal cells.     

Ezrin Is Required for the Functional Regulation of the Epithelial Sodium Proton Exchanger,NHE3

The sodium hydrogen exchanger isoform 3 (NHE3) mediates absorption of sodium, bicarbonate and water from renal and intestinal lumina. This activity is fundamental to the maintenance of a physiological plasma pH and blood pressure. To perform this function NHE3 must be present in the apical membrane of renal tubular and intestinal epithelia. The molecular determinants of this localization have not been conclusively determined, although linkage to the apical actin cytoskeleton through ezrin has been proposed. We set out to evaluate this hypothesis. Functional studies of NHE3 activity were performed on ezrin knockdown mice (Vil2^kd/kd) and NHE3 activity similar to wild-type animals detected. Interpretation of this finding was difficult as other ERM (ezrin/radixin/moesin) proteins were present. We therefore generated an epithelial cell culture model where ezrin was the only detectable ERM. After knockdown of ezrin expression with siRNA, radixin and moesin expression remained undetectable. Consistent with the animal ultrastructural data, cells lacking ezrin retained an epithelial phenotype but had shortened and thicker microvilli. NHE3 localization was identical to cells transfected with non-targeting siRNA. The attachment of NHE3 to the apical cytoskeleton was unaltered as assessed by fluorescent recovery after photobleaching (FRAP) and the solubility of NHE3 in Triton X-100. Baseline NHE3 activity was unaltered, however, cAMP-dependent inhibition of NHE3 was largely lost even though NHE3 was phosphorylated at serines 552 and 605. Thus, ezrin is not necessary for the apical localization, attachment to the cytoskeleton, baseline activity or cAMP induced phosphrylation of NHE3, but instead is required for cAMP mediated inhibition.     

Structural requirements for the apical sorting of human multidrug resistance protein 2 (ABCC2).

The human multidrug resistance protein 2 (MRP2, symbol ABCC2) is a polytopic membrane glycoprotein of 1545 amino acids which exports anionic conjugates across the apical membrane of polarized cells. A chimeric protein composed of C-proximal MRP2 and N-proximal MRP1 localized to the apical membrane of polarized Madin-Darby canine kidney cells (MDCKII) indicating involvement of the carboxy-proximal part of human MRP2 in apical sorting. When compared to other MRP family members, MRP2 has a seven-amino-acid extension at its C-terminus with the last three amino acids (TKF) comprising a PDZ-interacting motif. In order to analyze whether this extension is required for apical sorting of MRP2, we generated MRP2 constructs mutated and stepwise truncated at their C-termini. These constructs were fused via their N-termini to green fluorescent protein (GFP) and were transiently transfected into polarized, liver-derived human HepG2 cells. Quantitative analysis showed that full-length GFP-MRP2 was localized to the apical membrane in 73% of transfected, polarized cells, whereas it remained on intracellular membranes in 27% of cells. Removal of the C-terminal TKF peptide and stepwise deletion of up to 11 amino acids did not change this predominant apical distribution. However, apical localization was largely impaired when GFP-MRP2 was C-terminally truncated by 15 or more amino acids. Thus, neither the PDZ-interacting TKF motif nor the full seven-amino-acid extension were necessary for apical sorting of MRP2. Instead, our data indicate that a deletion of at least 15 C-terminal amino acids impairs the localization of MRP2 to the apical membrane of polarized cells.     

Identification of the apical membrane-targeting signal of the multidrug resistance-associated protein 2 (MRP2/MOAT)

The human canalicular multispecific organic anion transporter (cMOAT), known as the multidrug resistance-associated protein 2 (MRP2), is normally expressed in the liver and to a lesser extent in the kidney proximal tubules. In these tissues MRP2 specifically localizes to the apical membrane. The construction of MRP2 fused to the green fluorescent protein, and subsequent site-directed mutagenesis enabled the identification of a targeting signal in MRP2 that is responsible for its apical localization in polarized cells. The specific apical localization of MRP2 is due to a C-terminal tail that is not present in the basolaterally targeted MRP1. Deletion of three amino acids from the C-terminal of MRP2 (DeltaMRP2) causes the protein to be localized predominantly in the basolateral membrane in polarized Madin-Darby canine kidney cells. Interestingly, MRP2 expressed in a mouse leukemia cell line (L1210 cells) predominantly accumulates intracellularly with minimal cell membrane localization. In contrast, DeltaMRP2 was shown to predominantly localize in the cell membrane in L1210 cells. Increased transport of 2,4-dinitrophenyl glutathione from L1210 cells expressing DeltaMRP2 showed that the re-targeted protein retains its normal function.     

ERM stable knockdown by siRNA reduced in vitro migration and invasion of human SGC-7901 cells

Three closely related proteins, ezrin, radixin, and moesin (ERM), which primarily act as a linker between the plasma membrane and the cytoskeleton, are involved in many cellular functions, including regulation of actin cytoskeleton, control of cell shape, adhesion and motility, and modulation of signaling pathways. Although, ezrin is now recognized as a key component in tumor metastasis, the functional role of the radixin and moesin in tumor metastasis has not been established. In the present study, we chose highly metastatic human gastric carcinoma SGC-7901 cells, which express all of the ERM proteins as a model to examine the functional roles of these proteins in tumor metastasis. Ezrin, radixin or moesin stable knockdown SGC-7901 cell lines were established using siRNA methodology. In vitro cell migration and invasion studies showed that either ezrin, radixin or moesin specific deficiency in the cells caused the substantial reduction of the cell migration and invasion. Western blotting and immunofluorescence analysis showed that the expression of E-cadherin was also significantly increased when any member of ERM proteins was downregulated. Our results indicated that these three ERM proteins play similar roles in the SGC-7901 cell metastatic potential and their roles of upregulating the expression of E-cadherin may be important in tumor progression.     

Ezrin promotes morphogenesis of apical microvilli and basal infoldings in retinal pigment epithelium

Ezrin, a member of the ezrin/radixin/moesin (ERM) family, localizes to microvilli of epithelia in vivo, where it bridges actin filaments and plasma membrane proteins. Here, we demonstrate two specific morphogenetic roles of ezrin in the retinal pigment epithelium (RPE), i.e., the formation of very long apical microvilli and of elaborate basal infoldings typical of these cells, and characterize the role of ezrin in these processes using antisense and transfection approaches. In the adult rat RPE, only ezrin (no moesin or radixin) was detected at high levels by immunofluorescence and immunoelectron microscopy at microvilli and basal infoldings. At the time when these morphological differentiations develop, in the first two weeks after birth, ezrin levels increased fourfold to adult levels. Addition of ezrin antisense oligonucleotides to primary cultures of rat RPE drastically decreased both apical microvilli and basal infoldings. Transfection of ezrin cDNA into the RPE-J cell line, which has only trace amounts of ezrin and moesin, sparse and stubby apical microvilli, and no basal infoldings, induced maturation of microvilli and the formation of basal infoldings without changing moesin expression levels. Taken together, the results indicate that ezrin is a major determinant in the maturation of surface differentiations of RPE independently of other ERM family members.     

Characterization of the 5'-flanking region of the human multidrug resistance protein 2 (MRP2) gene and its regulation in comparison withthe multidrug resistance protein 3 (MRP3) gene.

The multidrug resistance proteins MRP2 (symbol ABCC2) and MRP3 (symbol ABCC3) are conjugate export pumps expressed in hepatocytes. MRP2 is localized exclusively to the apical membrane and MRP3 to the basolateral membrane. MRP2 mRNA is expressed at a high level under normal conditions, whereas MRP3 mRNA expression is low and increases only when secretion across the apical membrane by MRP2 is impaired. We studied some of the regulatory properties of the two human genes using transient transfection assays with promoter-luciferase constructs in HepG2 cells and cloned fragments of 1229 nucleotides and 1287 nucleotides of the MRP2 and MRP3 5'-flanking regions, respectively. The sequence between nucleotides -517 and -197 was decisive for basal MRP2 expression. Basal promoter activity of MRP3 was only 4% of that measured for MRP2. At submicromolar concentrations, the histone deacetylase inhibitor trichostatin A reduced the MRP2 reporter gene activity and expression of the protein. Disruption of microtubules with nocodazole decreased gene and protein expression of MRP2 and increased MRP3 reporter gene activity. The genotoxic 2-acetylaminofluorene decreased the activity of the human MRP2 reporter gene construct, but increased MRP3 gene activity and enhanced the amounts of mRNA and protein of MRP2 and MRP3. Thus, regulation of the expression of these ATP-dependent conjugate export pumps is not co-ordinate, but in part inverse. The inverse regulation of the two MRP isoforms is consistent with their distinct localization, their different mRNA expression under normal and pathophysiological conditions, and their different directions of substrate transport in polarized cells.     

ATP-binding cassette transporter isoform C2 localizes to the apical plasma membrane via interactions with scaffolding protein

ATP-binding cassette transporter isoform C2 (ABCC2) localizes to the apical plasma membrane in polarized cells. Apical localization of ABCC2 in hepatocytes plays an important role in biliary excretion of endobiotics and xenobiotics, but the mechanism by which ABCC2 localizes to the apical membrane has not been conclusively elucidated. Here, we investigate the role of scaffolding proteins on ABCC2 localization with a focus on the function of PDZK1 (post-synaptic density 95/disk large/zonula occludens-1 domain containing 1) in regulating ABCC2 localization. The C-terminal 77 residues of ABCC2 were used to probe interacting proteins from HepG2 cells. Protein mass fingerprinting identified PDZK1 as a major interacting protein. PDZK1 associated with the plasma membrane, most likely at the apical vacuoles of HepG2 cells. Affinity pull-down assays confirmed that the C-terminal NSTKF of ABCC2 bound to the fourth PDZ domain of PDZK1. Removal of this PDZ-binding motif significantly reduced the normal apical localization of ABCC2. In HepG2 cells, overexpression of this fourth domain overcame endogenous PDZK1 and reduced the ABCC2 localization at the apical membrane with a reciprocal increase of intracellular accumulation of mislocalized ABCC2. These results suggest a possible role for an interaction between ABCC2 and PDZK1 in apical localization of ABCC2 in hepatocytes.     

GLUT12 expression and regulation in murine small intestine and human Caco-2 cells

GLUT12 was cloned from the mammary cancer cell line MCF-7, but its physiological role still needs to be elucidated. To gain more knowledge of GLUT12 function in the intestine, we investigated GLUT12 subcellular localization in the small intestine and its regulation by sugars, hormones, and intracellular mediators in Caco-2 cells and mice. Immunohistochemical methods were used to determine GLUT12 subcellular localization in human and murine small intestine. Brush border membrane vesicles were isolated for western blot analyses. Functional studies were performed in Caco-2 cells by measuring α-methyl-d -glucose (αMG) uptake in the absence of sodium. GLUT12 is located in the apical cytoplasm, below the brush border membrane, and in the perinuclear region of murine and human enterocytes. In Caco-2 cells, GLUT12 translocation to the apical membrane and α-methyl- d -glucose uptake by the transporter are stimulated by protons, glucose, insulin, tumor necrosis factor-α (TNF-α), protein kinase C, and AMP-activated protein kinase. In contrast, hypoxia decreases GLUT12 expression in the apical membrane. Upregulation of TNF-α and hypoxia-inducible factor-1α ( HIF-1α) genes is found in the jejunal mucosa of diet-induced obese mice. In these animals, GLUT12 expression in the brush border membrane is slightly decreased compared with lean animals. Moreover, an intraperitoneal injection of insulin does not induce GLUT12 translocation to the membrane, as it occurs in lean animals. GLUT12 rapid translocation to the enterocytes’ apical membrane in response to glucose and insulin could be related to GLUT12 participation in sugar absorption during postprandial periods. In obesity, in which insulin sensitivity is reduced, the contribution of GLUT12 to sugar absorption is affected.     

Reconstitution of transport-active multidrug resistance protein 2 (MRP2; ABCC2) in proteoliposomes

The apical multidrug resistance protein MRP2 (symbol ABCC2) is an ATP-dependent export pump for anionic conjugates in polarized cells. MRP2 has only 48% amino acid identity with the paralog MRP1 (ABCC1). In this study we show that purified recombinant MRP2 reconstituted in proteoliposomes is functionally active in substrate transport. The Km values for ATP and LTC4 in the transport by MRP2 in proteoliposomes were 560 microM and 450 nM, respectively. This transport function of MRP2 in proteoliposomes was dependent on the amount of MRP2 protein present and was determined to 2.7 pmol x min(-1) x mg MRP2(-1) at 100 nM LTC4. Transport was competitively inhibited by the quinoline derivative MK571 with 50% inhibition at about 12 microM. Our data document the first reconstitution of transport-active purified recombinant MRP2. Binding and immunoprecipitation experiments indicated that MRP2 preferentially associates with the chaperone calnexin, but co-reconstitution studies using purified MRP2 and purified calnexin in proteoliposomes suggested that the LTC4 transport function of MRP2 is not dependent on calnexin. The purified, transport-active MRP2 may serve to identify additional interacting proteins in the apical membrane of polarized cells.     

Apical localization of PMCA2w/b is enhanced in terminally polarized MDCK cells

The “w” splice forms of PMCA2 localize to distinct membrane compartments such as the apical membrane of the lactating mammary epithelium, the stereocilia of inner ear hair cells or the post-synaptic density of hippocampal neurons. Previous studies indicated that PMCA2w/b was not fully targeted to the apical domain of MDCK cells but distributed more evenly to the lateral and apical membrane compartments. Overexpression of the apical scaffold protein NHERF2, however, greatly increased the amount of the pump in the apical membrane of these epithelial cells. We generated a stable MDCK cell line expressing non-tagged, full-length PMCA2w/b to further study the localization and function of this protein. Here we demonstrate that PMCA2w/b is highly active and shows enhanced apical localization in terminally polarized MDCK cells grown on semi-permeable filters. Reversible surface biotinylation combined with confocal microscopy of fully polarized cells show that the pump is stabilized in the apical membrane via the apical membrane cytoskeleton with the help of endogenous NHERF2 and ezrin. Disruption of the actin cytoskeleton removed the pump from the apical actin patches without provoking its internalization. Our data suggest that full polarization is a prerequisite for proper positioning of the PMCA2w variants in the apical membrane domain of polarized cells.     

A common Dubin-Johnson syndrome mutation impairs protein maturation and transport activity of MRP2 (ABCC2)

Absence of a functional multidrug resistance protein 2 (MRP2; symbol ABCC2) from the hepatocyte canalicular membrane is the molecular basis of Dubin- Johnson syndrome, an inherited disorder associated with conjugated hyperbilirubinemia in humans. In this work, we analyzed a relatively frequent Dubin-Johnson syndrome mutation that leads to an exchange of two hydrophobic amino acids, isoleucine 1173 to phenylalanine (MRP2I1173F), in a predicted extracellular loop of MRP2. HEK-293 cells stably transfected with MRP2I1173F cDNA synthesized a mutant protein that was mainly core-glycosylated, predominantly retained in the endoplasmic reticulum, and degraded by proteasomes. MRP2I1173F did not mediate ATP-dependent transport of leukotriene C(4) (LTC(4)) into vesicles from plasma membrane and endoplasmic reticulum preparations while normal MRP2 was functionally active. Human HepG2 cells were used to study localization of MRP2I1173F in a polarized cell system. Quantitative analysis showed that GFP-tagged MRP2I1173F was localized to the apical membrane in only 5% of transfected, polarized HepG2 cells compared with 80% for normal MRP2-GFP. Impaired protein maturation followed by proteasomal degradation of inactive MRP2I1173F explain the deficient hepatobiliary elimination observed in this group of Dubin-Johnson syndrome patients.     

Mammalian multidrug-resistance proteins (MRPs)

Subfamily C of the human ABC (ATP-binding cassette) superfamily contains nine proteins that are often referred to as the MRPs (multidrug-resistance proteins). The 'short' MRP/ABCC transporters (MRP4, MRP5, MRP8 and ABCC12) have a typical ABC structure with four domains comprising two membrane-spanning domains (MSD1 and MSD2) each followed by a nucleotide-binding domain (NBD1 and NBD2). The 'long' MRP/ABCCs (MRP1, MRP2, MRP3, ABCC6 and MRP7) have five domains with the extra domain, MSD0, at the N-terminus. The proteins encoded by the ABCC6 and ABCC12 genes are not known to transport drugs and are therefore referred to as ABCC6 and ABCC12 (rather than MRP6 and MRP9) respectively. A large number of molecules are transported across the plasma membrane by the MRPs. Many are organic anions derived from exogenous sources such as conjugated drug metabolites. Others are endogenous metabolites such as the cysteinyl leukotrienes and prostaglandins which have important signalling functions in the cell. Some MRPs share a degree of overlap in substrate specificity (at least in vitro), but differences in transport kinetics are often substantial. In some cases, the in vivo substrates for some MRPs have been discovered aided by studies in gene-knockout mice. However, the molecules that are transported in vivo by others, including MRP5, MRP7, ABCC6 and ABCC12, still remain unknown. Important differences in the tissue distribution of the MRPs and their membrane localization (apical in contrast with basolateral) in polarized cells also exist. Together, these differences are responsible for the unique pharmacological and physiological functions of each of the nine ABCC transporters known as the MRPs.     

Differentiation-dependent expression and localization of the class B type I scavenger receptor in intestine

The current study used the human Caco-2 cell line and mouse intestine to explore the topology of expression of the class B type I scavenger receptor (SR-BI) in intestinal cells. Results showed that intestinal cells expressed only the SR-BI isoform with little or no expression of the SR-BII variant. The expression of SR-BI in Caco-2 cells is differentiation dependent, with little or no expression in preconfluent undifferentiated cells. Analysis of Caco-2 cells cultured in Transwell porous membranes revealed the presence of SR-BI on both the apical and basolateral cell surface. Immunoblot analysis of mouse intestinal cell extracts demonstrated a gradation of SR-BI expression along the gastrocolic axis of the intestine, with the highest level of expression in the proximal intestine and decreasing to minimal expression levels in the distal intestine. Immunofluorescence studies with SR-BI-specific antibodies also confirmed this expression pattern. Importantly, the immunofluorescence studies also revealed that SR-BI immunoreactivity was most intense in the apical membrane of the brush border in the duodenum. The crypt cells did not show any reactivity with SR-BI antibodies. The localization of SR-BI in the jejunum was found to be different from that observed in the duodenum. SR-BI was present on both apical and basolateral surfaces of the jejunum villus. Localization of SR-BI in the ileum was also different, with little SR-BI detectable on either apical or basolateral membranes.Taken together, these results suggest that SR-BI has the potential to serve several functions in the intestine. The localization of SR-BI on the apical surface of the proximal intestine is consistent with the hypothesis of its possible role in dietary cholesterol absorption, whereas SR-BI present on the basolateral surface of the distal intestine suggests its possible involvement in intestinal lipoprotein uptake.     

Conjugate export pumps of the multidrug resistance protein (MRP) family: localization, substrate specificity, and MRP2-mediated drug resistance

The membrane proteins mediating the ATP-dependent transport of lipophilic substances conjugated to glutathione, glucuronate, or sulfate have been identified as members of the multidrug resistance protein (MRP) family. Several isoforms of these conjugate export pumps with different kinetic properties and domain-specific localization in polarized human cells have been cloned and characterized. Orthologs of the human MRP isoforms have been detected in many different organisms. Studies in mutant rats lacking the apical isoform MRP2 (symbol ABCC2) indicate that anionic conjugates of endogenous and exogenous substances cannot exit from cells at a sufficient rate unless an export pump of the MRP family is present in the plasma membrane. Several mutations in the human MRP2 gene have been identified which lead to the absence of the MRP2 protein from the hepatocyte canalicular membrane and to the conjugated hyperbilirubinemia of Dubin-Johnson syndrome. Overexpression of recombinant MRP2 confers resistance to multiple chemotherapeutic agents. Because of its function in the terminal excretion of cytotoxic and carcinogenic substances, MRP2 as well as other members of the MRP family, play an important role in detoxification and chemoprevention.     

Apical membrane segregation of phosphatidylinositol-4,5-bisphosphate influences parathyroid hormone 1 receptor compartmental signaling and localization via direct regulation of ezrin in LLC-PK1 cells

The parathyroid hormone 1 receptor (PTH1R), a primary regulator of mineral ion homeostasis, is expressed on both the apical and basolateral membranes of kidney proximal tubules and in the LLC-PK1 kidney cell line. In LLC-PK1 cells, apical PTH1R subpopulations are far more effective at signaling via phospholipase (PLC) than basolateral counterparts, revealing the presence of compartmental signaling. Apical PTH1R localization is dependent upon direct interactions with ezrin, an actin-membrane cross-linking scaffold protein. Ezrin undergoes an activation process that is dependent upon phosphorylation and binding to phosphatidylinositol-4,5-bisphosphate (PIP2), a lipid that is selectively concentrated to apical surfaces of polarized epithelia. Consistently, the intracellular probe for PIP2, GFP-PLCδ1-PH, localizes to the apical membranes of LLC-PK1 cells, directly overlapping ezrin and PTH1R expression. Activation of the apical PTH1R shifts the GFP-PLCδ1-PH probe from the apical membrane to the cytosol and basolateral membranes, reflecting domain-specific activation of PLC and hydrolysis of PIP2. This compartmental signaling is likely due to the polarized localization of PIP2, the substrate for PLC. PIP2 degradation using a membrane-directed phosphatase shifts ezrin localization to the cytosol and induces ezrin de-phosphorylation, processes consistent with inactivation. PIP2 degradation also shifts PTH1R expression from brush border microvilli to basolateral membranes and markedly blunts PTH-elicited activation of the MAPK pathway. Transient expression of ezrin in HEK293 cells shifts PTH1R expression from the plasma membrane to microvilli-like surface projections that also contain PIP2. As a result, ezrin enhances PTH mediated activation of the PLC pathway in this cell model with increasing total receptor surface expression. Collectively, these findings demonstrate that the apical segregation of PIP2 to the apical domains not only promotes the activation of ezrin and the subsequent formation of the PTH1R containing scaffold, but also ensures the presence of ample substrate for propagating the PLC pathway.