Abstract
The interaction of μ-opioid receptor (MOPr) with the neuronal membrane glycoprotein M6a is known to facilitate MOPr endocytosis in human embryonic kidney 293 (HEK293) cells. To further study the role of M6a in the post-endocytotic sorting of MOPr, we investigated the agonist-induced co-internalization of MOPr and M6a and protein targeting after internalization in HEK293 cells that co-expressed HA-tagged MOPr and Myc-tagged M6a. We found that M6a, MOPr, and Rab 11, a marker for recycling endosomes, co-localized in endocytotic vesicles, indicating that MOPr and M6a are primarily targeted to recycling endosomes after endocytosis. Furthermore, co-expression of M6a augmented the post-endocytotic sorting of δ-opioid receptors into the recycling pathway, indicating that M6a might have a more general role in opioid receptor post-endocytotic sorting. The enhanced post-endocytotic sorting of MOPr into the recycling pathway was accompanied by a decrease in agonist-induced receptor down-regulation of M6a in co-expressing cells. We tested the physiological relevance of these findings in primary cultures of cortical neurons and found that co-expression of M6a markedly increased the translocation of MOPrs from the plasma membrane to intracellular vesicles at steady state and significantly enhanced both constitutive and agonist-induced receptor endocytosis. In conclusion, our results strongly indicate that M6a modulates MOPr endocytosis and post-endocytotic sorting and has an important role in receptor regulation.
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Introduction
Opiates like morphine remain the best analgesic for treating chronic and serious pain. After prolonged or repeated drug administration, however, adaptive changes in the nervous system occur that are believed to contribute to physiological tolerance of and dependence on opiates and thereby limit the clinical utility of these drugs. These adaptive changes are initiated by the binding of opiate drugs to opioid receptors, which are also activated by endogenous opioid neuropeptides 1. There are three well-defined 'classical' types of the opioid receptors, μ-, δ- and κ-opioid receptors, which belong to the superfamily of G protein-coupled receptors (GPCRs) 2. The μ-opioid receptor (MOPr) mediates the action of most clinically important opiate drugs, like morphine, as well as drugs of abuse, such as heroin 3, 4, 5. Understanding the molecular mechanisms underlying the regulation of opioid receptors is a key step in the development of drugs and/or therapies that provide effective analgesia without causing detrimental adaptive responses.
As with other GPCRs, receptor phosphorylation occurs upon agonist binding. β-Arrestins then bind to phosphorylated receptors, causing the receptor to uncouple from G-proteins and leading to the targeting of receptors to clathrin-coated pits. Once the plasma membrane invaginates, vesiculation occurs as the GTPase dynamin wraps around the neck of the invagination and constricts upon GTP hydrolysis. These vesicles soon shed their clathrin coats and become early endosomes. Dissociation of ligands and β-arrestins from the receptors occurs in an acidified perinuclear compartment. Cytosolic phosphatases may dephosphorylate the receptors. The ligands are degraded while the receptors are either recycled to the plasma membrane for reactivation or downregulated by means of degradation in lysosomes 6, 7, 8, 9, 10, 11. Receptor-associated proteins play important roles during receptor endocytosis and intracellular trafficking. A number of proteins that bind to the MOPr have been recently identified and functionally characterized 12, 13, 14, 15, 16. We have previously identified and characterized a novel MOPr-interacting protein, the membrane glycoprotein M6a, which interacts with the MOPr and plays a role in receptor endocytosis in transfected human embryonic kidney 293 (HEK293) cells 17. Here, we demonstrate that the co-expression of M6a and MOPr in HEK293 cells facilitates the post-endocytotic sorting of internalized opioid receptors into the recycling pathway and decreases receptor proteolytic down-regulation. Importantly, we also present evidence from work in primary cultured neurons to suggest that M6a has a similar function in native neurons.
Results
Membrane glycoprotein M6a is a trafficking molecule
We recently reported that M6a facilitates the agonist-induced and constitutive endocytosis of the MOPr in transfected HEK293 cells 17. To investigate the trafficking of M6a in the absence of MOPr, we stably expressed an amino-terminally Myc-tagged M6a in HEK293 cells. As depicted in Figure 1, M6a localizes to both the plasma membrane and cytosolic vesicles in stably transfected HEK293 cells. Interestingly, after exposure to monensin, an inhibitor of vesicle recycling, M6a accumulates in cytosolic vesicle-like compartments. In contrast, after exposure to hypertonic sucrose (which blocks protein internalization via clathrin-coated pits), M6a is significantly fixed at the plasma membrane. These data confirm that M6a undergoes constitutive endocytosis and recycling.
M6a facilitates the recycling pathway of opioid receptors
To determine whether M6a modulates the post-endocytotic sorting of opioid receptors, we stably expressed an N-terminally HA-tagged MOPr or DOPr together with a Myc-tagged M6a in HEK293 cells. Numerous publications have shown that the MOPr and δ-opioid receptor differ in their post-endocytotic sorting 16, 18, 19, 20. In fact, internalized DOPr is known to be mainly sorted to the lysosome and degraded, whereas internalized MOPr is mainly sorted to the recycling endosomes for reactivation. Since M6a exhibits a strong interaction with MOPr 17, we carried out a 'pulse-chase' experiment to examine whether internalized M6a, together with MOPr, could be sorted to the recycling endosome. As expected, in HEK293 cells coexpressing MOPr and M6a, we found a remarkable co-localization of M6a and MOPr with transferrin, a marker for recycling endosomes 21, 22, in endocytotic vesicles (Figure 2A, arrow). In DOPr-expressing cells, no co-localization of DOPr with transferrin could be detected in endocytotic vesicles (Figure 2B, arrow head). Since M6a has also been shown to interact with DOPr 17, we investigated whether the interaction of M6a with DOPr could recruit internalized DOPr into recycling vesicles. As shown in Figure 2B (arrow), upon co-expression with M6a, internalized DOPr could be found to colocalize with transferrin in endocytotic vesicles. These data suggest that M6a might direct internalized opioid receptors into recycling endosomes during post-endocytotic sorting.
Since transferrin labels recycling endosomes as well as early endosomes, we next investigated whether M6a could influence the distribution of internalized receptors in specific endosomes. We found that acute agonist treatment (15 min) induced the co-internalization of MOPr-M6a or DOPr-M6a and their localization to EEA1-labeled early endosomes (Figure 3A, upper and lower panels, respectively). Internalized receptors, with or without co-expression of M6a, primarily localized to EEA1-labeled early endosomes (Figure 3A). Longer agonist treatments reduced the localization to early endosomes (data not shown). When the cells were stimulated for 30 min with MOPr agonist DAMGO or DOPr agonist DPDPE and then incubated for 15 min in agonist-free medium, there was a significant difference in the distribution of internalized receptors in Rab 11-labeled recycling endosomes. For internalized MOPr, agonist withdrawal led to receptor localization in Rab 11-labeled recycling endosomes; co-expression of M6a with MOPr increased this localization (Figure 3B, upper panel). In contrast, for internalized DOPr, after agonist withdrawal the receptor localization to Rab 11-labeled recycling endosomes was weak, although co-expression of M6a with DOPr also enhanced endosomal localization of DOPr (Figure 3B, lower panel). As depicted in Figure 3B, co-internalized DOPr-M6a was localized to Rab 11-labeled recycling endosomes (arrow, lower panel), whereas adjacent vesicles containing only internalized DOPr were not labeled by the anti-Rab 11 antibody (arrow head, lower panel), indicating that M6a directs internalized DOPr into recycling endosomes during post-endocytotic sorting. Furthermore, we quantified the percent localization of internalized receptors in EEA1-labeled early endosome or Rab 11-labeled recycling endosome. As depicted in Figure 3C, M6a did not significantly influence the localization of internalized receptors in the early endosome after acute agonist treatment; however, co-internalization of M6a significantly increased the localization of internalized receptors at the recycling endosome, especially for internalized DOPr. This result demonstrates that co-internalization of M6a with opioid receptors can influence the receptor recycling pathway in post-endocytotic sorting.
M6a attenuates agonist-induced down-regulation of the MOPr
Down-regulation of opioid receptors in response to chronic opioid treatment is a long-term adaptive process that results from the proteolytic degradation of internalized receptors. Our data suggest that co-expression of M6a can facilitate the postendocytotic sorting of opioid receptors into the recycling pathway. It is reasonable to suggest, therefore, that M6a-enhanced MOPr recycling might decrease receptor endosomal sorting to lysosomes for degradation and thus decrease receptor down-regulation. In fact, we found that agonist-induced down-regulation of MOPr was significantly reduced in cells that were co-expressing M6a (Figure 4). After an extended exposure (16 h) to DAMGO, we detected that only about 25% of MOPr were downregulated in cells that were co-expressing MOPr and M6a, compared to about 42% down-regulation in cells expressing MOPr alone (Figure 4).
M6a increases the intracellular localization of MOPr in cortical neurons
We next tested whether M6a affects MOPr regulation in primary cultured neurons of the rat cortex. Since endogenous expression of MOPr and M6a proteins in cultured cortical neurons from the embryonic day 17 embryos was below the detection level for immunocytochemistry and/or a functional assay (data not shown), we transiently transfected the neurons with vectors that drive expression of MOPr and M6a. The expression of MOPr and/or M6a proteins could be detected between 1 day and 2 weeks after transfection. Using trypan blue staining to distinguish between dead and live cells, we found that exogenous expression of MOPr and/or M6a did not influence the health of the neurons during the 2 weeks of culture (data not shown). At 5-6 days after transfection, the neurons were viable and well-developed and thus were used in the following experiments. Werner et al. 23 reported that endogenous M6A localizes to the cell surface and is much less abundant in intracellular compartments. Endogenous MOPr is mainly localized to the plasma membrane of neurons 24. In our cultured cortical neurons expressing either M6a or MOPr, M6a was predominantly localized to intracellular vesicles (Figure 5A), whereas MOPr was predominantly localized to the plasma membrane (Figure 5B). Similar to our previous findings in HEK293 cells 17, the co-expression of MOPr with M6a significantly increased the intracellular localization of MOPrs (Figure 5C) compared with cultured cortical neurons expressing MOPr alone (Figure 5B). These findings suggest that M6a can enhance the constitutive endocytosis of MOPr in neurons.
Co-expression of M6a augments agonist-induced and constitutive MOPr endocytosis in cortical neurons
Next, we performed surface-labeling to investigate the constitutive and agonist-induced endocytosis of membrane MOPr and M6a in cortical neurons. As shown in Figure 6A and 6B, M6a and MOPr were specifically surface-labeled at the plasma membrane of both the cell body and processes. After 30 min at 37 °C without agonist treatment, constitutive receptor endocytosis was hardly visible in neurons expressing MOPr alone (Figure 6C), whereas co-expression of M6a with MOPr increased constitutive co-internalization of MOPr and M6a (Figure 6D, yellow vesicles). In addition, agonist-induced MOPr endocytosis after 30 min of DAMGO treatment (Figure 6E) was enhanced by the co-expression of M6a (Figure 6F). These findings indicate that MOPr and M6a are colocalized and co-internalized in primary cortical neurons and that M6a enhances the constitutive and agonist-induced MOPr internalization.
We further quantified the effect of M6a on MOPr endocytosis. As depicted in Figure 7A, co-expression of M6a significantly enhanced both constitutive and agonist-induced endocytosis of MOPrs. Although M6a and DM20 share high homology and belong to the same proteolipid protein (PLP) family of tetraspan membrane proteins 25, co-expression of DM20 did not influence MOPr endocytosis. A shorter truncation mutant (129-255 aa) of M6a was previously shown to interact with MOPr and attenuate agonist-induced receptor endocytosis 17. Consistent with that finding in transfected HEK293 cells 17, co-expression of this dominant negative M6a truncation mutant (nM6a) significantly decreased MOPr endocytosis (Figure 7A). Moreover, through imaging using a confocal microscope, we found that the μ-agonist DAMGO clearly induced co-internalization and co-localization of MOPr and M6a (Figure 6D and 6F), whereas it failed to cause co-localization of MOPr and DM20 (Figure 7B). In addition, in many neurons, the co-expression of nM6a markedly decreased agonist-induced MOPr endocytosis (Figure 7C). These findings indicate that M6a-enhanced MOPr endocytosis in neurons is due to M6a itself.
Discussion
The membrane glycoprotein M6a is a member of the PLP family of tetraspan membrane proteins and is expressed primarily in neurons 25, 26, 27. It is generally believed that glycoproteins of the PLP family function as structural proteins for myelination. M6a, however, is also thought to function as a modulator for neurite outgrowth 28 and spine formation 29, and also acts as a nerve growth factor-gated Ca2+ channel in neuronal differentiation 30. The present findings, together with our previous work 17, indicate that M6a could function as a scaffolding, anchoring, or adaptor protein in the intracellular trafficking of certain GPCRs and thus demonstrate a new function for a protein in the PLP family.
In transfected HEK293 cells, hypertonic sucrose, an inhibitor of receptor internalization 31, significantly increased M6a distribution at the plasma membrane, whereas monensin, an inhibitor of vesicle recycling 32, 33, greatly decreased the surface localization and increased the intracellular distribution of M6a. These findings suggest that M6a is a constitutive trafficking molecule that may affect the constitutive trafficking of its interacting proteins. Indeed, both in HEK293 cells and in primary cortical neurons, co-expression of M6a augmented the intracellular distribution of MOPrs.
After internalization, the regulation of opioid receptor sorting between recycling and degradation pathways is of particular interest owing to its importance in cell signaling in response to opioids. MOPr and DOPr differ significantly in their post-endocytotic sorting. Internalized DOPr is mainly targeted to lysosomes for degradation, whereas MOPr and its splice variants have distinct properties that direct them to recycle back to the cell surface upon agonist treatment 18, 19, 20, 34. As yet, the mechanism by which post-endocytotic sorting of opioid receptors occurs is still obscure.
A protein termed GASP (GPCR-associated sorting protein), which binds preferentially to the carboxyl tail of the DOPr, was identified as a candidate for a post-endocytotic sorting protein 16. The interaction of DOPr with GASP directs the internalized receptors into the lysosomal pathway destined for proteolytic degradation. Our data suggest that the interaction of MOPr or DOPr with M6a facilitates the sorting of internalized receptors into the recycling pathway for reactivation and impairs the sorting of receptors into lysosomes for degradation. It is reasonable to propose that the differential post-endocytotic sorting of MOPr and DOPr could be caused by selective binding of M6a and GASP to the receptors. In support of this idea, GASP binds much less strongly to MOPr than to DOPr 16, and we observed a lower interaction of M6a with DOPr compared to MOPr 17. We speculate that interaction of MOPr with M6a induces recycling of MOPr, whereas the interaction of DOPr with GASP targets DOPr to lysosomes for degradation. This hypothesis is further supported by the finding that over-expression of M6a leads to the sorting of internalized DOPr into the recycling pathway (Figure 3B and 3C).
The detailed molecular mechanism of M6a-mediated receptor trafficking is still under investigation. It is possible that M6a influences the formation of the actin cytoskeletal network and thus induces receptor transport into the cytoplasm. In support of this hypothesis, M6a was observed to be selectively enriched in the actin-rich lamellipodia and philopodia at the leading edge of neuronal growth cones 35 and transported to these sites in an actin-dependent manner 36. Additionally, it has been suggested that an association with the actin cytoskeleton is a common property of members of the PLP family 37. It is also possible that M6a might change some property of clathrin-coated vesicles and endosomes, for example charge or pH, and thereby influence vesicle transport and endosome sorting. An acidified endosome is important for the recycling of internalized receptors 32, 33. In support of this hypothesis, tetraspan proteolipids, including members of the PLP family, are known to contribute to the formation of pore structures in a wide spectrum of cellular systems 38. Moreover, Rhombex-29, a new member of the PLP family, was suggested to be responsible for transporting H+ 39.
In conclusion, we have demonstrated that M6a functions in opioid receptor trafficking both in HEK293 cells and in primary cultured neurons. M6a might also modulate the intracellular trafficking of certain other receptors since M6a interacts with a number of GPCRs 17. It has been well documented that MOPr endocytosis reduces the development of opioid tolerance by promoting fast receptor resensitization and recycling 12, 40, 41, 42, 43, 44, 45, 46, 47. It is therefore reasonable to suggest that M6a-enhanced endocytosis/recycling of MOPrs attenuates the development of opiate tolerance.
Materials and Methods
Epitope tagging and cloning of cDNA
The MOPr (Gi: 6981309) and δ-opioid receptor (Gi: 31543370) were tagged at the amino terminus with the influenza hemagglutinin-HA epitope tag (YPYDVPDYA) using polymerase chain reaction (PCR); these fragments were then subcloned into the pEAK10 expression vector containing the puromycin resistance gene (Edge Bio Systems, Gaithersburg, MD, USA) to generate the plasmids pEAK10-HA-MOPr and pEAK10-HA-DOPr, respectively. As described previously 17, the coding region of M6a (GI: 31981997), M6a negative truncation mutant (nM6a, amino acid 129-255 of M6a) or DM20 (GI: 200408) was subcloned into pCMV-Myc (Clontech, Heidelberg, Germany) by PCR to generate an amino-terminally Myc-tagged M6a, nM6a or DM20. The Myc-M6a was further subcloned into the pcDNA3.1 expression vector containing the hygromycin resistance gene (Invitrogen, Karlsruhe, Germany) by PCR.
Cell culture
HEK293 cells were maintained in DMEM (BF12-604F, Cambrex, Verviers, Belgium) supplemented with 10% fetal bovine serum (FBS) (S0115, Biochrom AG, Berlin, Germany) and relevant antibiotics in a humidified incubator with an atmosphere containing 10% CO2 at 37 °C. For all experiments, cells were grown overnight in DMEM supplemented with 10% FBS without any antibiotics and pre-incubated in UltraMEM (BE12-743F, Cambrex) for about 30 min prior to different treatments. Unless otherwise specified, all cells were treated in UltraMEM.
Generation of stable cell lines
According to the manufacturer's protocol, HEK293 cells were first transfected with pEAK10-HA-MOPr, pEAK10-HA-DOPr or pcDNA3.1-Myc-M6a plasmid using LipofectamineTM 2000 (Invitrogen, Karlsruhe, Germany). Stable transfectants were selected in the presence of 1.25 μg/ml puromycin (Sigma, Deisenhofen, Germany) or 400 μg/ml hygromycin B (PAA Laboratories GmbH, Pasching, Germany). To generate a stable cell line co-expressing HA-MOPr and Myc-M6a, stable HA-MOPr cells were subjected to a second round of transfection with pcDNA3.1-Myc-M6a plasmid as described above and selected in the presence of 1.25 μg/ml puromycin and 400 μg/ml hygromycin B. Stable lines expressing similar densities of both receptors were used for further study. Receptor and/or M6a expression were monitored using confocal microscopy and western blot analysis.
Immunocytochemistry
HEK293 cells were grown overnight on poly-L-lysine-treated coverslips. After treatment or without treatment, the cells were fixed with Zamboni's fixative (4% paraformaldehyde and 0.2% picric acid in phosphate buffer, pH 6.9) for 20 min at room temperature (RT). After a wash with TPBS (10 mM Tris, 10 mM phosphate buffer, 137 mM NaCl and 0.05% thimerosal, pH 7.4), specimens were incubated for 3 min each in 50% and 100% methanol to permeabilize the membrane. Subsequently, specimens were washed several times in TPBS and then pre-incubated with TPBS containing 3% normal goat serum (NGS) at RT for 1 h. Then, cells were incubated with mouse anti-Myc antibody (Clontech) at a concentration of 0.2 μg/ml in TPBS containing 1% NGS at RT for 1 h. Bound primary antibodies were detected with cyanine 3.18-conjugated secondary antibodies (1:400 or 3.75 μg/ml, Jackson ImmunoResearch, West Grove, PA). Cells were then permanently mounted in DPX (Fluka, NeuUlm, Germany). Specimens were examined using a Leica TCS-NT laser-scanning confocal microscope equipped with a krypton/argon laser.
For further characterization of the endocytic pathway in MOPr and M6a in transfected HEK293 cells, the receptor and M6a were surface-labeled with anti-HA (Gramsch Laboratories, Schwabhausen, Germany) and anti-M6a antibodies (Medical & Biological Laboratories, Göttingen, Germany) at a final concentration of 1.0 μg/ml in UltraMEM medium at 4 °C for 1 h. After treatment as indicated, the cells were fixed, permeabilized, and blocked as described above. Afterwards, the cells were incubated with goat anti-EEA1 or Rab 11 antibody (Santa Cruz Biotechnology, Santa Cruz, CA) at a concentration of 4 μg/ml in TPBS containing 1% NGS at RT for 3 h. Antibody-labeled receptor, M6a and endogenous EEA1 (or Rab 11) were detected with a mixture of Alexa Fluor 488- (1:1,200, Molecular Probes, Invitrogen), Cyanine 3.18- (1:400, Jackson ImmunoResearch) and Alexa Fluor 647- (1:500, Molecular Probes) conjugated second antibodies, respectively. Alexa Fluor 488 was imaged with 488 nm excitation and 530 nm emission filters; Cyanine 3.18 was imaged with 568 nm excitation and 570-630 nm band pass emission filters; and Alexa Fluor 647 (or Cyanine 5.18) was imaged with 647 nm excitation and 665 nm long pass emission filters. To characterize the effect of M6a on receptor distribution in EEA1- or Rab 11-labeled vesicles, vesicles with co-localization of the receptor, EEA1, Rab 11 and/or M6a were counted. The percentage of receptors targeted to EEA1- or Rab 11-positive endosomes in the presence or absence of M6a is shown.
Similarly, for immunocytochemistry in primary cortical neurons, the cells were fixed, and the distribution of MOPr and M6a was determined using rabbit anti-HA (0.2 μg/ml) and/or mouse anti-Myc (0.2 μg/ml) antibodies followed by Alexa Fluor 488- and/or Cyanine 3.18-conjugated secondary antibodies. To observe the endocytosis of surface MOPr and/or M6a, cells were first surface-labeled with a rabbit anti-HA and/or a rat anti-M6a antibody at a final concentration of 2.0 μg/ml in UltraMEM medium at 4 °C for 30 min at 6 days post-transfection. Subsequently, the cells were incubated in the presence or absence of 10 μM DAMGO ([D-Ala2, Me-Phe4, Glyol5 enkephalin) for 30 min prior to fixation and permeabilization. The bound primary antibodies were detected with Alexa Fluor 488- and/or Cyanine 3.18-conjugated secondary antibodies as described above.
Transferrin trafficking
A previously described 'pulse-chase' assay 34, 48 was used to estimate the degree to which a 'pulse' of internalized MOPr/DOPr and M6a was accessible to a subsequent 'chase' of endocytosed transferrin. In short, receptors and M6a were surface-labeled with anti-HA and anti-M6a antibodies (1 μg/ml, each) at 4 °C for 1 h. Cells were first incubated with agonist at 37 °C for 30 min to drive internalization of antibody-labeled receptor and M6a and then rinsed with EDTA-supplemented phosphate-buffered saline. Subsequently, cells were rewarmed to 37 °C for 20 min in agonist-free medium containing 5 μg/ml Alexa Fluor 488-conjugated transferrin (Molecular Probes, Eugene, Oregon, USA). Finally, cells were fixed and permeabilized, and antibody-labeled receptor and M6a were detected with a mixture of Cyanine 5.18- and Cyanine 3.18-conjugated second antibodies, as described above.
Radioligand binding assays
The binding studies were performed by saturation binding assays on total proteins prepared from stably transfected HEK293 cells expressing HA-MOPr with and without co-expression of Myc-M6a. The number of [3H]DAMGO binding sites (Bmax) was calculated by Scatchard analysis using at least seven concentrations of [3H]DAMGO in a range from 0.25 to 10 nM as previously described 49. Nonspecific binding was determined as radioactivity bound in the presence of 1 μM unlabeled DAMGO. The radioligand binding assay was sensitive enough to calculate the receptor amount. The number of [3H]DAMGO binding sites in a membrane binding assay reflects the amount of total MOPrs, which can be used to evaluate the receptor down-regulation.
Primary cultures of the cerebral cortex and transfection
All animal procedures were approved by the Otto-von-Guericke-University Magdeburg. Cortical cultures were obtained from E17 Sprague Dawley rat embryos (Charles River) and prepared as described previously 50. The freshly prepared cortical cells were transfected with pEAK10-HA-MOPr, pCMV-Myc-M6a, pCMV-Myc-nM6a and/or pCMV-Myc-DM20 plasmids using Rat Neuron Nucleofector Solution according to the manufacturer's protocol (Amaxa Inc., USA). After transfection, the cells were seeded at about 6×105 cells per well in a 12-well plate with poly-L-lysine-coated coverslips for immunocytochemistry and at about 4×105 cells per well in a 24-well poly-L-lysine-coated plate for quantitative assays. The cells grew in Neurobasal medium (Invitrogen, Paisley, UK) supplemented with 2% B-27, 0.5 mM L-glutamine, 100 U/ml penicillin and 100 μg/ml streptomycin. Cells were cultured at 37 °C and 5% CO2 in a humidified incubator. On the fourth day after seeding the cells and then every second day thereafter, 50% of the culture medium was replaced. Cells were used for experiments 6 days after transfection. Neurons, astrocytes and oligodendrocytes in the cultures were characterized by immunocytochemistry using antibodies for MAP2 (M4403, Sigma), GFAP (GP52, Progen, Heidelberg, Germany) and CNPase (C5922, Sigma), respectively.
Quantitative analysis of receptor internalization
Newly prepared cortical cells (E17) were co-transfected with the mixed plasmids of pEAK10-HA-MOPr plus pCMV-Myc, pCMV-Myc-M6a, pCMV-Myc-DM20 or pCMV-Myc-nM6a as indicated, and then seeded at 4×105 cells per well in a poly-L-lysine-coated 24-well plate. At 6 days after transfection, the cells were precultured in UltraMEM medium for 30 min and then surface-labeled with an anti-HA antibody as described above. Subsequently, the cells were treated with or without 1 μM DAMGO in UltraMEM medium at 37 °C for 30 min and then fixed. Following fixation and wash, the cells were incubated with peroxidase-conjugated anti-rabbit antibody (1:1,000, Amersham) in UltraMEM for 2 h at RT. Plates were developed with 250 μl of ABTS solution (Roche Molecular Biomedicals, Mannheim, Germany). After 15 min, 200 μl of the substrate solution from each well was transferred to a 96-well plate and analyzed at 405 nm using an Expert Plus Microplate Reader (ASYS, Eugendorf, Austria). Receptor endocytosis was evaluated as the loss of surface-labeled receptors.
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Acknowledgements
We thank Karina Schäfer, Michaela Böx and Evelyn Kahl (Department of Pharmacology and Toxicology, Otto-von-Guericke-University, Magdeburg, Germany) for excellent technical assistance. This work was supported by grants HO 1027/10-1 and SFB 426/A2 from the Deutsche Forschungsgemeinschaft (to VH) and BMBF-grant 01ZZ0407 (to TK).
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Liang, YJ., Wu, DF., Stumm, R. et al. Membrane glycoprotein M6A promotes μ-opioid receptor endocytosis and facilitates receptor sorting into the recycling pathway. Cell Res 18, 768–779 (2008). https://doi.org/10.1038/cr.2008.71
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DOI: https://doi.org/10.1038/cr.2008.71
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