trans-Golgi retention of a plasma membrane protein: mutations in the cytoplasmic domain of the asialoglycoprotein receptor subunit H1 result in trans-Golgi retention.

Unlike the wild-type asialoglycoprotein receptor subunit H1 which is transported to the cell surface, endocytosed and recycled, a mutant lacking residues 4-33 of the 40-amino acid cytoplasmic domain was found to be retained intracellularly upon expression in different cell lines. The mutant protein accumulated in the trans-Golgi, as judged from the acquisition of trans-Golgi-specific modifications of the protein and from the immunofluorescence staining pattern. It was localized to juxtanuclear, tubular structures that were also stained by antibodies against galactosyltransferase and gamma-adaptin. The results of further mutagenesis in the cytoplasmic domain indicated that the size rather than the specific sequence of the cytoplasmic domain determines whether H1 is retained in the trans-Golgi or transported to the cell surface. Truncation to less than 17 residues resulted in retention, and extension of a truncated tail by an unrelated sequence restored surface transport. The transmembrane segment of H1 was not sufficient for retention of a reporter molecule and it could be replaced by an artificial apolar sequence without affecting Golgi localization. The cytoplasmic domain thus appears to inhibit interaction(s) of the exoplasmic portion of H1 with trans-Golgi component(s) for example by steric hindrance or by changing the positioning of the protein in the membrane. This mechanism may also be functional in other proteins.

Dynamic interactions of the asialoglycoprotein receptor subunits with coated pits. Enhanced interactions of H2 following association with H1.

Lateral mobility studies comparing native and mutated membrane proteins, combined with treatments that alter clathrin lattice structure, can measure membrane protein-coated pit interactions in intact cells (Fire, E., Zwart, D., Roth, M. G., and Henis, Y. I. (1991) J. Cell Biol. 115, 1585-1594). We applied this approach to study the interactions of the H1 and H2 human asialoglycoprotein receptor subunits with coated pits. The lateral mobilities of singly expressed and coexpressed H1 and H2B (the H2 species that reaches the cell surface) were measured by fluorescence photobleaching recovery. They were compared with mutant proteins, H1(5A) (Tyr-5 replaced by Ala) and H2(5A) (Phe-5 replaced by Ala). While the mobile fractions of H1, H2B, and their mutants were similar, the lateral diffusion rate (measured by D, the lateral diffusion coefficient) was significantly slower for H1, whether expressed alone or with H2B. Coexpression with H1 reduced D of H2B to that of H1. Disruption of the clathrin lattices by hypertonic medium elevated D of H1, H1(5A), H2B, and H2(5A) to the same final level, without affecting their mobile fractions. Cytosol acidification, which retains altered clathrin lattices attached to the membrane and prevents coated vesicle formation, immobilized part of the H1 molecules, reflecting stable entrapment in "frozen" coated pits. H1(5A), H2B, and H2(5A) were not affected; however, coexpression of H2B with H1 conferred the sensitivity to cytosol acidification on H2B. Our results suggest that H1 lateral mobility is inhibited by dynamic interactions with coated pits in which Tyr-5 is involved. H2B resembles H1(5A) rather than H1, and its interactions with coated pits are weaker; efficient interaction of H2B with coated pits depends on complex formation with H1.

The two subunits of the asialoglycoprotein receptor contain different sorting information.

The human asialoglycoprotein receptor, an endocytic transport receptor of the basolateral surface of hepatocytes, is a hetero-oligomer of two homologous subunits H1 and H2. The cytoplasmic domain of H1 has been shown previously to contain a tyrosine-based signal for endocytosis and basolateral sorting. Here, we have investigated sorting determinants within subunit H2 and their contribution to the targeting of the hetero-oligomeric receptor complex. Despite extensive sequence homology, H2 expressed separately in fibroblast cells was endocytosed poorly, and mutation of phenylalanine 5 (corresponding to the critical tyrosine in H1) did not further reduce internalization. Consistent with this observation, ligand uptake by receptors composed of H1 lacking tyrosine 5 and H2 was inefficient. With respect to polarized transport in Madin-Darby canine kidney cells, H2 could not be analyzed separately, because in the absence of H1 subunit H2 was completely degraded intracellularly. Coexpression of both subunits yielded ligand-binding receptors located specifically on the basolateral surface. The mutant H1(5A) (tyrosine 5 replaced by alanine) is approximately 55% apical in the absence of H2. In cells expressing H1(5A) together with H2, however, subunit H2 directed receptor complexes exclusively to the basolateral domain. Phenylalanine 5 is not essential for basolateral transport. Thus, whereas the endocytosis signal of the hetero-oligomeric asialoglycoprotein receptor resides exclusively in subunit H1, polarized transport to the basolateral domain of Madin-Darby canine kidney cells may involve two signals, only one of which is active for endocytosis.

Related signals for endocytosis and basolateral sorting of the asialoglycoprotein receptor.

The major subunit of the human asialoglycoprotein receptor contains signals for efficient endocytosis and specific basolateral expression in polarized Madin-Darby canine kidney cells, both of which are located within its 40-residue cytoplasmic domain. The aromatic residue in this segment, tyrosine 5, which is necessary for efficient clustering into clathrin-coated pits at the plasma membrane, is also necessary for exclusive basolateral delivery. Mutation of this residue to alanine resulted in a nonpolar expression of the protein. Replacement of tyrosine 5 with phenylalanine yielded almost wild-type rates of endocytosis as well as specific basolateral expression, indicating that tyrosine phosphorylation is not essential for either sorting step. The close similarity between the two sorting signals was further corroborated by deletion mutants showing that the amino-terminal 10 residues of the cytoplasmic domain are sufficient for basolateral polarity and efficient endocytosis. The kinetics of appearance of newly synthesized wild-type and mutant receptor protein at the apical and basolateral surfaces indicate that these proteins are sorted intracellularly and are transported directly to the respective domains. Mutants affected in basolateral sorting lost polarity, i.e, appeared to similar extents on both surfaces, indicating that there is no significant apical sorting information elsewhere in the protein. The close correlation between endocytosis and basolateral polarity suggests common recognition mechanisms at the plasma membrane and in the trans-Golgi network.

Phorbol ester-induced redistribution of the ASGP receptor is independent of receptor phosphorylation.

Like virtually all endocytic receptors, the human asialoglycoprotein (ASGP) receptor is phosphorylated by protein kinase C at serine residues within the cytoplasmic domains of its two subunits H1 and H2. Activation of protein kinase C by phorbol esters results in hyperphosphorylation and in a concomitant net redistribution of receptors to intracellular compartments (down-regulation) in HepG2 cells. To test whether there is a causal relationship between receptor hyperphosphorylation and redistribution, we examined the effect of phorbol ester treatment on the ASGP receptor composed of either wild-type subunits or of mutant subunits lacking any cytoplasmic serine residues in transfected NIH3T3 fibroblast and COS-7 cells. Although the wild-type subunits were hyperphosphorylated in fibroblast cells, the distribution of neither the wild-type nor the mutant receptors was affected. In contrast, phorbol ester treatment of transfected COS-7 cells induced down-regulation of both wild-type and mutant receptors. These findings indicate that redistribution of the receptor is independent of its cytoplasmic serines and is not caused by receptor phosphorylation.

Endocytosis by the asialoglycoprotein receptor is independent of cytoplasmic serine residues.

The human asialoglycoprotein (ASGP) receptor, like most other plasma membrane receptors, has previously been shown to be phosphorylated at serine residues within the cytoplasmic domain. Phorbol esters, which activate protein kinase C, cause hyperphosphorylation and down-regulation of the ASGP receptor in HepG2 cells. To test the importance of serine residues for receptor traffic and function, we have mutated all the cytoplasmic serines of the two receptor subunits H1 (at positions 16 and 37) and H2 (at positions 12, 13, and 55) to alanines or glycines. Stable transfected fibroblast cell lines expressing either mutant H1 alone or both mutant subunits together were created and compared to cell lines expressing the respective wild-type proteins. Mutant and wild-type subunits were found to have very similar distributions between the cell surface and intracellular compartments. Constitutive internalization of H1 alone and ligand uptake and degradation by cells expressing both receptor subunits were not affected by the mutations. Cytoplasmic serines and serine phosphorylation are thus not essential for receptor function and intracellular traffic. Analysis of individual serine mutations identified serine-12 of subunit H2 as the major site of phosphorylation in the ASGP receptor.

Endocytosis of the ASGP receptor H1 is reduced by mutation of tyrosine-5 but still occurs via coated pits.

The clustering of plasma membrane receptors in clathrin-coated pits depends on determinants within their cytoplasmic domains. In several cases, individual tyrosine residues were shown to be necessary for rapid internalization. We have mutated the single tyrosine at position 5 in the cytoplasmic domain of the major subunit H1 of the asialoglycoprotein receptor to alanine. Expressed in fibroblasts cells, the mutant protein was accumulated in the plasma membrane, and its rate of internalization was reduced by a factor of four. The residual rate of endocytosis, however, was still significantly higher than that of resident plasma membrane proteins. Upon acidification of the cytoplasm, which specifically inhibits the formation of clathrin-coated vesicles but not uptake of the fluid phase marker Lucifer yellow, residual endocytosis was blocked. By immunoelectron microscopy mutant H1 could be directly demonstrated in coated pits. The fraction of wild-type and mutant H1 present in coated pits as determined by immunogold localization correlated well with the respective rates of internalization. Thus, mutation of tyrosine-5 only partially inactivates recognition of H1 for incorporation into coated pits.

Charged residues are major determinants of the transmembrane orientation of a signal-anchor sequence.

Uncleaved signal-anchor sequences of membrane proteins inserted into the endoplasmic reticulum initiate the translocation of either the amino-terminal or the carboxyl-terminal polypeptide segment across the bilayer. Which topology is acquired is not determined by the apolar segment of the signal but rather by the hydrophilic sequences flanking it. To study the role of charged residues in determining the membrane topology, the insertion of mutants of the asialoglycoprotein receptor H1, a single-spanning protein with a cytoplasmic amino terminus, was analyzed in transfected COS-7 cells. When the charged amino acids flanking the hydrophobic signal were mutated to residues of opposite charge, half the polypeptides inserted with the inverted orientation. When, in addition, the amino-terminal domain of the mutant protein was truncated, approximately 90% of the polypeptides acquired the inverted topology. The transmembrane orientation appears to be primarily determined by the charges flanking the signal sequence but is modulated by the domains to be translocated.

Endocytosis and recycling of subunit H1 of the asialoglycoprotein receptor is independent of oligomerization with H2.

The human asialoglycoprotein receptor is composed of two homologous subunits, H1 and H2. By expressing the two subunits in transfected fibroblast cell lines, it has been shown previously that the formation of a hetero-oligomeric complex is necessary for the transport of H2 to the plasma membrane and for high-affinity ligand binding. Here we show that subunit H1, when expressed in the absence of H2, is capable of internalization through coated pits and recycling. The kinetics of these processes are very similar to those of the H1-H2 complex. To study endocytosis in the absence of ligand binding, the cell surface was labeled at 4 degrees C with the 125I-iodinated impermeant reagent sulfosuccinimidyl-3-(4-hydroxyphenyl) propionate, the cells were incubated at 37 degrees C for different times and the amount of internalized receptor was determined by protease digestion of surface proteins and immunoprecipitation. Similarly, recycling of surface-labeled and then internalized receptor protein was studied by monitoring its reappearance on the surface in the presence of exogenous protease. Our results show that subunit H1 contains all the signals necessary for receptor endocytosis and recycling independent of ligand binding.

A hepatocyte-specific basolateral membrane protein is targeted to the same domain when expressed in Madin-Darby canine kidney cells.

Different mechanisms for polarized sorting of apical and basolateral plasma membrane proteins appear to be operative in different cell types. In hepatocytes, all proteins are first transported to the basolateral surface, where sorting (probably signal-mediated) of apical proteins then takes place. In contrast, in Madin-Darby canine kidney (MDCK) cells, proteins are directly transported from the trans-Golgi network to their appropriate plasma membrane domain. In order to study the differences in the sorting requirements of the two cell types, we have expressed a hepatocyte-specific basolateral membrane protein, the asialoglycoprotein receptor H1, in MDCK cells. H1 was found to be specifically transported to the basolateral domain also in this heterologous system, suggesting that either the same basolateral targeting signal is operative in both cell types or, more likely, that basolateral transport occurs "by default," i.e. without the requirement for a sorting signal.

Redistribution of acetylcholine receptors on developing rat myotubes.

The mechanism of formation of acetylcholine receptor (AChR) clusters at developing mammalian endplates was investigated in vitro, using intercostal muscles from embryonic rats. The muscles were explanted in organ culture with the spinal cord attached, as described previously (Ziskind-Conhaim, L., and M. J. Dennis (1981) Dev. Biol. 85: 243-251). AChRs on the myofibers were labeled with [125I]-alpha-bungarotoxin shortly before clusters appeared and subsequently were cultured in unlabeled toxin for 1 day. Autoradiography of the cultured fibers demonstrated the presence of labeled clusters of AChRs indicating that the AChRs in the newly formed clusters arise from AChRs that had previously been uniformly distributed on the muscle surface.