Intracellular routing of wild-type and mutated polymeric immunoglobulin receptor in hippocampal neurons in culture

Certain epithelial cells synthesize the polymeric immunoglobulin receptor (pIgR) to transport immunoglobulins (Igs) A and M into external secretions. In polarized epithelia, newly synthesized receptor is first delivered to the basolateral plasma membrane and is then, after binding the Ig, transcytosed to the apical plasma membrane, where the receptor-ligand complex is released by proteolytic cleavage. In a previous work (Ikonen et al., 1993), we implied the existence of a dendro-axonal transcytotic pathway for the rabbit pIgR expressed in hippocampal neurons via the Semliki Forest Virus (SFV) expression system. By labeling surface-exposed pIgR in live neuronal cells, we now show (a) internalization of the receptor from the dendritic plasma membrane to the dendritic early endosomes, (b) redistribution of the receptor from the dendritic to the axonal domain, (c) inhibition of this movement by brefeldin A (BFA) and (d) stimulation by the activation of protein kinase C (PKC) via phorbol myristate acetate (PMA). In addition, we show that a mutant form of the receptor lacking the epithelial basolateral sorting signal is directly delivered to the axonal domain of hippocampal neurons. Although this mutant is internalized into early endosomes, no transcytosis to the dendrites could be observed. In epithelial Madin-Darby Canine Kidney (MDCK) cells, the mutant receptor could also be internalized into basolaterally derived early endosomes. These results suggest the existence of a dendro-axonal transcytotic pathway in neuronal cells which shares similarities with the basolateral to apical transcytosis in epithelial cells and constitute the basis for the future analysis of its physiological role.     

Identification and functional characterization of protein kinase C isozymes in platelets and HEL cells.

To determine if selective activation of individual isozymes of protein kinase C (PKC) might explain the apparently divergent effects of PKC stimulation on platelets, we purified and characterized the isozymes from both platelets and human erythroleukemia (HEL) cells, a cell line that has many features of megakaryocytes. Two peaks of platelet PKC activity were resolved by hydroxylapatite chromatography; immunoblot analysis revealed that these two peaks represented the alpha and beta isozymes of PKC. In contrast, HEL cells produced only a single peak that contained the beta isozyme. None of the other PKC isozymes were detected in these fractions. The cytosol of platelets and HEL cells, however, were both found to contain the PKC-delta isozyme. Northern hybridization analyses and mRNA amplification by the polymerase chain reaction demonstrated the presence of mRNA encoding the alpha, beta, and delta PKC isozymes in platelets, but only the beta and delta isozymes in HEL cells. Phorbol myristate acetate (PMA), thrombin, or an endoperoxide analog induced the phosphorylation of the 47-kDa substrate of PKC (pleckstrin) found in platelets and HEL cells; preincubation of either HEL cells or platelets with PMA reduced the intracellular Ca2+ rise induced by thrombin. Thus, although both HEL cells and platelets contain PKC-beta and the recently described PKC-delta isozymes, the widely distributed alpha isozyme of PKC is absent in HEL cells; however, isozymes other than PKC-alpha are sufficient for some PMA-mediated functions that are similar to those seen in stimulated platelets.     

Gs alpha stimulates transcytosis and apical secretion in MDCK cells through cAMP and protein kinase A

Recent evidence suggests a role for heterotrimeric G proteins in vesicular transport. Cholera toxin, which activates Gs alpha by ADP- ribosylation, has been reported to stimulate both apical secretion (Pimplikar, S.W., and K. Simons. 1993. Nature (Lond.). 352:456-458) and apically directed transcytosis (Bomsel, M., and K.E. Mostov. 1993. J. Biol. Chem. 268:25824-25835) in MDCK cells, via a cAMP-independent mechanism. Here, we demonstrate that apical secretion and apically directed transcytosis are significantly stimulated by agents that elevate cellular cAMP. Forskolin, which activates adenylyl cyclase directly, and 8BrcAMP augment both transport processes in MDCK cells. The increase is not limited to receptor-mediated transport (polymeric Ig receptor), since transcytosis of ricin, a galactose-binding lectin, is similarly stimulated. The effects of elevated cellular cAMP on apical secretion and transcytosis are apparently mediated via protein kinase A (PKA), as they are inhibited by H-89, a selective PKA inhibitor. Experiments employing a 17 degrees C temperature block indicate that cAMP/PKA acts at a late, possibly rate-limiting stage in the transcytotic pathway, after translocation of internalized markers into the apical cytoplasm. However, no significant stimulus of apical recycling was observed in the presence of FSK, suggesting that cAMP/PKA either affects transcytosis at a level proximal to apical early endosomes and/or specifically increases the efficiency by which transcytosing molecules are delivered to the apical plasma membrane. Finally, we overexpressed wild-type Gs alpha and a mutant, Q227L, which constitutively activates adenylyl cyclase, in MDCK cells. Although Q227L increased transcytosis more than wild-type Gs alpha, neither construct was as effective as FSK in stimulating transcytosis, arguing against a significant role of Gs alpha in transcytosis independent of cAMP and PKA.     

Polarized sorting of the polymeric immunoglobulin receptor in the exocytotic and endocytotic pathways is controlled by the same amino acids.

Polarized epithelial cells can sort plasma membrane proteins to the apical or basolateral domain either by direct targeting from the trans-Golgi network (TGN) or by targeting to one surface, followed by endocytosis and transcytosis to the opposite surface. In Madin-Darby canine kidney (MDCK) cells, targeting of the polymeric immunoglobulin receptor (pIgR) to the basolateral surface is controlled by a sorting signal residing in the membrane proximal 17 amino acids of the cytoplasmic domain of this receptor. We have recently found that individual mutations at any of three residues in this signal, His656, Arg657 and Val660, substantially decrease targeting from the TGN to the basolateral surface and correspondingly increase targeting from the TGN to the apical surface. Here we report that these mutations decrease the recycling of basolaterally endocytosed pIgR to that surface, and correspondingly increase its transcytosis to the apical surface. This effect occurred in mutant pIgRs that either contained the full-length cytoplasmic domain or were truncated to contain only the 17-residue basolateral targeting signal, and was independent of phosphorylation of pIgR at Ser664. Our results indicate that polarized sorting of the pIgR in the endocytotic and exocytotic pathways are controlled by the same amino acids.     

Role of Tyrosine Phosphorylation in Ligand-induced Regulation of Transcytosis of the Polymeric Ig Receptor

The polymeric Ig receptor (pIgR) transcytoses its ligand, dimeric IgA (dIgA), from the basolateral to the apical surface of epithelial cells. Although the pIgR is constitutively transcytosed in the absence of ligand, binding of dIgA stimulates transcytosis of the pIgR. We recently reported that dIgA binding to the pIgR induces translocation of protein kinase C, production of inositol triphosphate, and elevation of intracellular free calcium. We now report that dIgA binding causes rapid, transient tyrosine phosphorylation of several proteins, including phosphatidyl inositol-specific phospholipase C-γl. Protein tyrosine kinase inhibitors or deletion of the last 30 amino acids of pIgR cytoplasmic tail prevents IgA-stimulated protein tyrosine kinase activation, tyrosine phosphorylation of phospholipase C-γl, production of inositol triphosphate, and the stimulation of transcytosis by dIgA. Analysis of pIgR deletion mutants reveals that the same discrete portion of the cytoplasmic domain, residues 727–736 (but not the Tyr734), controls both the ability of pIgR to cause dIgA-induced tyrosine phosphorylation of the phospholipase C-γl and to undergo dIgA-stimulated transcytosis. In addition, dIgA transcytosis can be strongly stimulated by mimicking phospholipase C-γl activation. In combination with our previous results, we conclude that the protein tyrosine kinase(s) and phospholipase C-γl that are activated upon dIgA binding to the pIgR control dIgA-stimulated pIgR transcytosis.     

Selective alterations in biosynthetic and endocytic protein traffic in Madin-Darby canine kidney epithelial cells expressing mutants of the small GTPase Rac1

Madin-Darby canine kidney (MDCK) cells expressing constitutively active Rac1 (Rac1V12) accumulate a large central aggregate of membranes beneath the apical membrane that contains filamentous actin, Rac1V12, rab11, and the resident apical membrane protein GP-135. To examine the roles of Rac1 in membrane traffic and the formation of this aggregate, we analyzed endocytic and biosynthetic trafficking pathways in MDCK cells expressing Rac1V12 and dominant inactive Rac1 (Rac1N17). Rac1V12 expression decreased the rates of apical and basolateral endocytosis, whereas Rac1N17 expression increased those rates from both membrane domains. Basolateral-to-apical transcytosis of immunoglobulin A (IgA) (a ligand for the polymeric immunoglobulin receptor [pIgR]), apical recycling of pIgR-IgA, and accumulation of newly synthesized GP-135 at the apical plasma membrane were all decreased in cells expressing Rac1V12. These effects of Rac1V12 on trafficking pathways to the apical membrane were the result of the delivery and trapping of these proteins in the central aggregate. In contrast to abnormalities in apical trafficking events, basolateral recycling of transferrin, degradation of EGF internalized from the basolateral membrane, and delivery of newly synthesized pIgR from the Golgi to the basolateral membrane were all relatively unaffected by Rac1V12 expression. Rac1N17 expression had little or no effect on these postendocytic or biosynthetic trafficking pathways. These results show that in polarized MDCK cells activated Rac1 may regulate the rate of endocytosis from both membrane domains and that expression of dominant active Rac1V12 specifically alters postendocytic and biosynthetic membrane traffic directed to the apical, but not the basolateral, membrane.     

Comparison of FcRn‐ and pIgR‐Mediated Transport in MDCK Cells by Fluorescence Confocal Microscopy

Protein delivery across polarized epithelia is controlled by receptor‐mediated transcytosis. Many studies have examined basolateral‐to‐apical trafficking of polymeric IgA (pIgA) by the polymeric immunoglobulin receptor (pIgR). Less is known about apical‐to‐basolateral transcytosis, the direction the neonatal Fc receptor (FcRn) transports maternal IgGs across intestinal epithelia. To compare apical‐to‐basolateral and basolateral‐to‐apical transcytosis, we co‐expressed FcRn and pIgR in Madin‐Darby canine kidney (MDCK) cells and used pulse‐chase experiments with confocal microscopy to examine transport of apically applied IgG Fcγ and basolaterally applied pIgA. Fcγ and pIgA trafficking routes were initially separate but intermixed at later chase times. Fcγ was first localized near the apical surface, but became more equally distributed across the cell, consistent with concomitant transcytosis and recycling. By contrast, pIgA transport was strongly unidirectional: pIgA shifted from near the basolateral surface to an apical location with increasing time. Some Fcγ and pIgA fluorescence colocalized in early (EEA1‐positive), recycling (Rab11a‐positive), and transferrin (Tf)‐positive common/basolateral recycling endosomes. Fcγ became more enriched in Tf‐positive endosomes with time, whereas pIgA was sorted from these compartments. Live‐cell imaging revealed that vesicles containing Fcγ or pIgA shared similar mobility characteristics and were equivalently affected by depolymerizing microtubules, indicating that both trafficking routes depended to roughly the same extent on intact microtubules.     

PKC-epsilon regulates basolateral endocytosis in human T84 intestinal epithelia: role of F-actin and MARCKS

Protein kinase C (PKC) and the actin cytoskeleton are criticaleffectors of membrane trafficking in mammalian cells. In polarized epithelia, the role of these factors in endocytic events at either theapical or basolateral membrane is poorly defined. In the present study,phorbol 12-myristate 13-acetate (PMA) and other activators of PKCselectively enhanced basolateral but not apical fluid-phase endocytosisin human T84 intestinal epithelia. Stimulation of basolateralendocytosis was blocked by the conventional and novel PKC inhibitorGö-6850, but not the conventional PKC inhibitor Gö-6976,and correlated with translocation of the novel PKC isoform PKC-. PMAtreatment induced remodeling of basolateral F-actin. The actindisassembler cytochalasin D stimulated basolateral endocytosis andenhanced stimulation of endocytosis by PMA, whereas PMA-stimulated endocytosis was blocked by the F-actin stabilizers phalloidin andjasplakinolide. PMA induced membrane-to-cytosol redistribution of theF-actin cross-linking protein myristoylated alanine-rich C kinasesubstrate (MARCKS). Cytochalasin D also induced MARCKS translocationand enhanced PMA-stimulated translocation of MARCKS. A myristoylatedpeptide corresponding to the phosphorylation site domain of MARCKSinhibited both MARCKS translocation and PMA stimulation of endocytosis.MARCKS translocation was inhibited by Gö-6850 but notGö-6976. The results suggest that a novel PKC isoform, likelyPKC-, stimulates basolateral endocytosis in model epithelia by amechanism that involves F-actin and MARCKS.

     

An epsilonPKC-selective inhibitor attenuates back phosphorylation of a low molecular weight protein in cardiac myocytes

We have studied epsilon PKC-mediated phosphorylation events in neonatal cardiac myocytes using back phosphorylation. 3 nM 4-beta 12-myristate-13-acetate (PMA)-intact cell treatment preferentially activates epsilon PKC in these cells (Circ. Res. 76 (1995) 654) and caused decreased 32P incorporation (back phosphorylation) into an approximately 18-kDa protein. This response required physiological levels of free Mg(2+) and short (3-5 min) incubation periods in back phosphorylation assays. Introduction of a selective epsilon PKC translocation inhibitor (epsilon V1) into these cells attenuated the 3 nM PMA-induced back phosphorylation response while translocation inhibitors to the classical PKC or deltaPKC isozymes were without effect. Pretreatment of our cells with endothelin-1 (ET1) had similar effects to 3 nM PMA albeit the magnitude of the ET1 back phosphorylation response was about one-half that of 3 nM PMA. Our results suggest that epsilon PKC phosphorylates an approximately 18-kDa protein found in the particulate cell fraction of neonatal cardiac myocytes. Epsilon PKC modulates diverse cardiac responses including contraction, ion channel functions, hypertrophy, and ischemic preconditioning. Characterization of epsilon PKC-selective phosphotransferase events may reveal novel regulatory mechanisms for this enzyme in neonatal cardiac myocytes.     

Association of Rab25 and Rab11a with the Apical Recycling System of Polarized Madin–Darby Canine Kidney Cells

Recent evidence suggests that apical and basolateral endocytic pathways in epithelia converge in an apically located, pericentriolar endosomal compartment termed the apical recycling endosome. In this compartment, apically and basolaterally internalized membrane constituents are thought to be sorted for recycling back to their site of origin or for transcytosis to the opposite plasma membrane domain. We report here that in the epithelial cell line Madin–Darby Canine Kidney (MDCK), antibodies to Rab11a label an apical pericentriolar endosomal compartment that is dependent on intact microtubules for its integrity. Furthermore, this compartment is accessible to a membrane-bound marker (dimeric immunoglobulin A [IgA]) internalized from either the apical or basolateral pole, functionally defining it as the apical recycling endosome. We have also examined the role of a closely related epithelial-specific Rab, Rab25, in the regulation of membrane recycling and transcytosis in MDCK cells. When cDNA encoding Rab25 was transfected into MDCK cells, the protein colocalized with Rab11a in subapical vesicles. Rab25 transfection also altered the distribution of Rab11a, causing the coalescence of immunoreactivity into multiple denser vesicular structures not associated with the centrosome. Nevertheless, nocodazole still dispersed these vesicles, and dimeric IgA internalized from either the apical or basolateral membrane was detected in endosomes labeled with antibodies to both Rab11a and Rab25. Overexpression of Rab25 decreased the rate of IgA transcytosis and of apical, but not basolateral, recycling of internalized ligand. Conversely, expression of the dominant-negative Rab25T26N did not alter either apical recycling or transcytosis. These results indicate that both Rab11a and Rab25 associate with the apical recycling system of epithelial cells and suggest that Rab25 may selectively regulate the apical recycling and/or transcytotic pathways.     

Direct interaction between Rab3b and the polymeric immunoglobulin receptor controls ligand-stimulated transcytosis in epithelial cells

We have examined the role of rab3b in epithelial cells. In MDCK cells, rab3b localizes to vesicular structures containing the polymeric immunoglobulin receptor (pIgR) and located subjacent to the apical surface. We found that GTP-bound rab3b directly interacts with the cytoplasmic domain of pIgR. Binding of dIgA to pIgR causes a dissociation of the interaction with rab3b, a process that requires dIgA-mediated signaling, Arg657 in the cytoplasmic domain of pIgR, and possibly GTP hydrolysis by rab3b. Binding of dIgA to pIgR at the basolateral surface stimulates subsequent transcytosis to the apical surface. Overexpression of GTP-locked rab3b inhibits dIgA-stimulated transcytosis. Together, our data demonstrate that a rab protein can bind directly to a specific cargo protein and thereby control its trafficking.     

Intracellular pH on translocation of protein kinase C isozymes in rat pinealocytes

In rat pinealocytes, cytoplasmic alkalization causes protein kinase C (PKC) translocation, but the isozyme involved is not known. In this study, we investigated the effect of cytoplasmic alkalization on membrane-associated PKCalpha, delta, epsilon, and zeta, four isozymes present in the rat pineal gland. Treatment with NH(4)Cl, which had no effect on PKCzeta, caused a sustained increase in membrane-associated PKCalpha, delta, and epsilon that lasted for at least 60 min. The effect of NH(4)Cl on PKCalpha, delta, and epsilon was reduced by sodium propionate, an agent that counteracts the effect of NH(4)Cl on intracellular pH. Both sodium propionate and 5-(N,N-hexamethylene)amiloride (HMA), two treatments that abolished the effect of norepinephrine on cytoplasmic alkalization, also reduced norepinephrine-mediated increases in membrane-associated PKCalpha, delta, and epsilon. In contrast, these two treatments did not have an effect on the increase in membrane-associated PKC isozymes caused by 4beta-phorbol 12-myristate 13-acetate (PMA), an active phorbol ester, even though HMA was effective in abolishing PMA-mediated increases in intracellular pH. These results, apart from demonstrating that cytoplasmic alkalization by itself can cause translocation of PKCalpha, delta, and epsilon in rat pinealocytes, also indicate that the norepinephrine-stimulated cytoplasmic alkalization plays an important role in transducing signals from the adrenergic receptor to selective PKC isozymes. However, PKC translocation stimulated directly by PMA does not appear to be sensitive to changes in intracellular pH.     

Detergent insoluble microdomains are not involved in transcytosis of polymeric Ig receptor in FRT and MDCK cells

In polarized epithelial cells, sorting of proteins and lipids to the apical or basolateral domain of the plasma membrane can occur via direct or indirect (transcytotic) pathways from the trans Golgi network (TGN). The 'rafts' hypothesis postulates that the key event for direct apical sorting of some transmembrane proteins and the majority of GPI-anchored proteins depends on their association with glycosphingolipid and cholesterol enriched microdomains (rafts). However, the mechanism of indirect sorting to the apical membrane is not clear. The polyimmunoglobulin receptor (pIgR) is one of the best studied proteins that follow the transcytotic pathway. It is normally delivered from the TGN to the basolateral surface of polarized Madin–Darby Canine Kidney (MDCK) cells from where it transports dIgA or dIgM to the apical surface. We have studied the intracellular trafficking of pIgR in Fischer rat thyroid cells (FRT), and have investigated the sorting machinery involved in transcytosis of this receptor in both FRT and MDCK cells. We found that, in contrast with MDCK cells, a significant amount (∼30%) of pIgR reaches the apical surface by a direct pathway. Furthermore, in both cell lines it does not associate with Triton X-100-insoluble microdomains, suggesting that at least in these cells 'rafts' are not involved in basolateral to apical transcytosis.     

Basolateral to apical transcytosis in polarized cells is indirect and involves BFA and trimeric G protein sensitive passage through the apical endosome

We have used temperature and nocodazole blocks in an in vivo basolateral to apical transcytosis assay to dissociate the early transcytotic steps occurring during the formation of transcytotic vesicles and their microtubule-dependent translocation into the apical region, from the late steps when transcytotic cargo is delivered into the apical media. We found that polarized MDCK cells transfected with rabbit polymeric IgA receptor (pIgA-R) internalize basolaterally added pIgA-R ligand ([Fab]2 fragment of IgG against the receptor's ectodomain) at 17 degrees C but do not deliver it to the apical PM. Instead, the ligand accumulates in an apically localized transcytotic compartment, distal to the basolateral endosome and the microtubule- requiring translocation step. We have characterized this compartment and show that it is distinct from basolateral transferrin recycling endosomes, basolateral early endosomes or late endosomes or lysosomes. The apical transcytotic compartment colocalizes with the compartment containing apically recycling membrane markers (ricin and apically internalized pIgA-R ligand) but is distinct from the compartment receiving apically internalized fluid phase marker (BSA). This compartment is an intermediate station of the overall pathway since transcytotic ligand can exit the compartment and be released into the apical medium when cells preloaded at 17 degrees C are subsequently incubated at 37 degrees C. We have used this system to examine the effect of Brefeldin A (BFA) and the involvement of trimeric GTPases in the late (post apical transcytotic compartment) steps of the transcytotic pathway. We found that addition of BFA or cholera toxin, a known activator of Gs alpha, to cells preloaded with transcytotic ligand at 17 degrees C significantly inhibits the exit of ligand from the apical transcytotic compartment. General structure and function of the apical endosome are not affected since neither BFA nor cholera toxin inhibit the recycling of apically internalized membrane markers (ricin and pIgA-R ligand) from the same compartment. The data suggest that transcytosis connects the "membrane-sorting" sub-domain of the basolateral endosome with a homologous sub-domain of the apical endosome and that exit of transcytosing cargo from the apical endosome is controlled by a BFA and trimeric G protein sensitive mechanism, distinct from that used for recycling of apically internalized proteins (ricin or pIgA-R).     

IgG transcytosis and recycling by FcRn expressed in MDCK cells reveals ligand-induced redistribution

The neonatal Fc receptor (FcRn) transports IgG across epithelial cells and recycles serum IgG. FcRn binds IgG at the acidic pH of endosomes and releases IgG at the basic pH of blood. We expressed rat FcRn in polarized MDCK cells and demonstrated that it functions in transcytosis and recycling of IgG. In the absence of IgG, FcRn is distributed predominantly apically, but redistributes to basolateral locations upon IgG addition, indicating that ligand binding induces a signal that stimulates transcytosis. FcRn transcytoses IgG more efficiently in the apical to basolateral than the reverse direction when IgG is internalized by receptor-mediated endocytosis at acidic pH or by fluid phase endocytosis at basic pH. The PI 3-kinase inhibitor wortmannin disrupts basolateral recycling and transcytosis in both directions, but only minimally reduces apical recycling. Confocal imaging and quantitative IgG transport studies demonstrate that apically-internalized IgG recycles to the apical surface mainly from wortmannin-insensitive apical early endosomes, whereas FcRn-IgG complexes that transcytose to the basolateral surface pass through downstream Rab11-positive apical recycling endosomes and transferrin-positive common endosomal compartments.     

Apical to basolateral transcytosis and apical recycling of immunoglobulin G in trophoblast-derived BeWo cells: effects of low temperature, nocodazole, and cytochalasin D

The murine neonatal Fc receptor, FcRn, carries out two functions: materno-fetal IgG delivery and maintenance of serum IgG homeostasis. During human pregnancy maternal IgG is transferred across placental syncytiotrophoblasts presumably by the human homolog of FcRn, hFcRn. Trophoblast-derived BeWo cells express hFcRn endogenously and can be considered as a model system to investigate IgG transport in syncytiotrophoblasts. Using a pulse-chase protocol, we here demonstrate that polarized BeWo cells exhibit not only apical to basolateral transcytosis but also apical IgG recycling. Thus, for the first time we demonstrate that epithelial cells can be involved in both materno-fetal IgG transmission and regulation of serum IgG levels. Lowering the temperature from 37 to 16 degrees C reduced, but did not block, IgG recycling and transcytosis. Microtubule-disruption by nocodazole did not influence transcytosis or apical recycling. Disassembly of filamentous actin by cytochalasin D stimulated apical endocytosis and recycling, while transcytosis remained unaffected. In summary, in BeWo cells apically internalized IgG enters both a transcytotic and recycling pathway. While the transcytotic route is temperature-sensitive but independent from microtubules and actin filaments, the apical recycling pathway is temperature-influenced and stimulated by actin disassembly, suggestive for the involvement of distinct endosome subcompartments in transcytosis and recycling.     

Signal transduction by the polymeric immunoglobulin receptor suggests a role in regulation of receptor transcytosis

Many membrane traffic events that were previously thought to be constitutive recently have been found to be regulated by a variety of intracellular signaling pathways. The polymeric immunoglobulin receptor (pIgR) transcytoses dimeric IgA (dIgA) from the basolateral to the apical surface of polarized epithelial cells. Transcytosis is stimulated by binding of dIgA to the pIgR, indicating that the pIgR can transduce a signal to the cytoplasmic machinery responsible for membrane traffic. We report that dIgA binding to the pIgR causes activation of protein kinase C (PKC) and release of inositol 1,4,5- trisphosphate (IP3). The IP3 causes an elevation of intracellular Ca. Artificially activating PKC with phorbol myristate acetate or poisoning the calcium pump with thapsigargin stimulates transcytosis of pIgR, while the intracellular Ca chelator BAPTA-AM inhibits transcytosis. Our data suggest that ligand-induced signaling by the pIgR may regulate membrane traffic via well-known second messenger pathways involving PKC, IP3, and Ca. This may be a model of a general means by which membrane traffic is regulated by receptor-ligand interaction and signaling pathways.     

MAL regulates clathrin-mediated endocytosis at the apical surface of Madin-Darby canine kidney cells

MAL is an integral protein component of the machinery for apical transport in epithelial Madin-Darby canine kidney (MDCK) cells. To maintain its distribution, MAL cycles continuously between the plasma membrane and the Golgi complex. The clathrin-mediated route for apical internalization is known to differ from that at the basolateral surface. Herein, we report that MAL depends on the clathrin pathway for apical internalization. Apically internalized polymeric Ig receptor (pIgR), which uses clathrin for endocytosis, colocalized with internalized MAL in the same apical vesicles. Time-lapse confocal microscopic analysis revealed cotransport of pIgR and MAL in the same endocytic structures. Immunoelectron microscopic analysis evidenced colabeling of MAL with apically labeled pIgR in pits and clathrin-coated vesicles. Apical internalization of pIgR was abrogated in cells with reduced levels of MAL, whereas this did not occur either with its basolateral entry or the apical internalization of glycosylphosphatidylinositol-anchored proteins, which does not involve clathrin. Therefore, MAL is critical for efficient clathrin-mediated endocytosis at the apical surface in MDCK cells.     

IL-10 production induced by HIV-1 Tat stimulation of human monocytes is dependent on the activation of PKC beta(II) and delta isozymes

The effect of HIV-1 Tat protein on the production of IL-10, an immunosuppressive cytokine, was examined in human primary monocytes obtained from healthy HIV-1-negative blood donors. As expected and in agreement with our previous data, a dose-dependent induction of IL-10 was observed. In addition, we showed that this induction is mediated by the PKC pathway: in the presence of Ro 31-8220, an inhibitor of all PKC isozymes, or after 48 h of PMA treatment, Tat protein becomes unable to stimulate IL-10 production. Among the 11 PKC isozymes, eight (PKC alpha, beta(I), beta(II), delta, epsilon, eta, zeta, mu) are expressed in monocytes. In this study, by analyzing the translocation to the membrane after Tat stimulation, we showed that PKC alpha, beta(I), beta(II), delta and epsilon isozymes are activated by Tat. Moreover, by combining different approaches including selective PKC inhibitors (G?6983, G?6976, hispidin and rottlerin), we showed that PKC beta(II) and delta isozymes are essential for the activation of IL-10 production in human monocytes following stimulation by HIV-1 Tat protein.     

Reconstitution of transcytosis in SLO-permeabilized MDCK cells: existence of an NSF-dependent fusion mechanism with the apical surface of MDCK cells.

Recently, it was demonstrated that delivery from the trans-Golgi network (TGN) to the basolateral surface of Madin-Darby canine kidney (MDCK) cells required N-ethylmaleimide-sensitive factor (NSF)-alpha soluble NSF attachment protein (SNAP)-SNAP receptor (SNARE) complexes, while delivery from the TGN to the apical surface was independent of NSF-alpha SNAP-SNARE. To determine if all traffic to the apical surface of this cell line was NSF independent, we reconstituted the transcytosis of pre-internalized IgA to the apical surface and recycling to the basolateral surface. Transcytosis and the recycling of IgA required ATP and cytosol, and both were inhibited by treatment with N-ethylmaleimide. This inhibition was reversed by the addition of recombinant NSF. Botulinum neurotoxin serotype E, which is known to cleave the 25,000 Da synaptosomal associated protein, inhibited both transcytosis and recycling, although incompletely. We conclude that membrane traffic to a target membrane is not determined by utilizing a single molecular mechanism for fusion. Rather, a target membrane, e.g. the apical plasma membrane of MDCK cells, may use multiple molecular mechanisms to fuse with incoming vesicle.