Subcellular localization of human neutral ceramidase expressed in HEK293 cells

We previously reported that rat and mouse neutral ceramidases were mainly localized to plasma membranes as a type II integral membrane protein and partly detached from the cells via processing of the N-terminal/anchor sequence when expressed in HEK293 cells [M. Tani, H. Iida, M. Ito, O-glycosylation of mucin-like domain retains the neutral ceramidase on the plasma membranes as a type II integral membrane protein, J. Biol. Chem. 278 (2003) 10523-10530]. In contrast, the human homologue was exclusively detected in mitochondria when expressed in HEK293 and MCF7 cells as a fusion protein with green fluorescent protein at the N-terminal of the enzyme [S.E. Bawab, P. Roddy, T. Quian, A. Bielawska, J.J. Lemasters, Y.A. Hannun, Molecular cloning and characterization of a human mitochondrial ceramidase, J. Biol. Chem. 275 (2000) 21508-21513]. Given this discrepancy, we decided to clone the neutral ceramidase from human kidney cDNA and re-examine the intracellular localization of the enzyme when expressed in HEK293 cells. The putative amino acid sequence of the newly cloned enzyme was identical to that reported for human neutral ceramidase except at the N-terminal; the new protein was 19 amino acids longer at the N-terminal. We found that the putative full-length human neutral ceramidase was transported to plasma membranes, but not to mitochondria, possibly via a classical ER/Golgi pathway and localized mainly in plasma membranes when expressed in HEK293 cells. The N-terminal-truncated mutant, previously reported as a human mitochondrial ceramidase, was also weakly expressed in HEK293 cells but mainly released into the medium possibly due to the insufficient signal/anchor sequence.     

The signal anchor and stem regions of the beta-galactoside alpha 2,6-sialyltransferase may each act to localize the enzyme to the Golgi apparatus.

The beta-galactoside alpha 2,6-sialyltransferase has been localized to the trans cisternae of the Golgi apparatus and the trans Golgi network where it transfers sialic acid residues to terminal positions on N-linked oligosaccharides. It is a type II transmembrane protein possessing a 9-amino acid amino-terminal cytoplasmic tail, a 17-amino acid signal anchor domain, and a 35-amino acid stem region which tethers the large luminal catalytic domain to the membrane anchor. Previous work has demonstrated that the soluble sialytransferase catalytic domain is rapidly secreted from Chinese hamster ovary cells. These results suggest that the signals for Golgi apparatus localization do not reside in the catalytic domain of the enzyme but must reside in the cytoplasmic tail, signal anchor domain, and/or stem region. To determine which amino-terminal regions are required for Golgi apparatus localization, mutant sialyltransferase proteins were constructed by in vitro oligonucleotide-directed mutagenesis, expressed in Cos-1 cells, and localized by indirect immunofluorescence microscopy. Signal cleavage-sialyltransferase mutants which consist of only the stem and catalytic domain of the enzyme are not rapidly secreted but are retained intracellularly and predominantly localized to the Golgi apparatus. However, deletion of either the stem region or the cytoplasmic tail of the membrane-bound sialyltransferase does not alter its Golgi apparatus localization. In addition, sequential replacement of the amino acids of the sialyltransferase signal anchor domain with amino acids from the signal anchor domain of a plasma membrane protein, the influenza virus neuraminidase does not alter the Golgi apparatus localization of the sialyltransferase. These observations suggest that sequences in the signal anchor region and stem region allow the Golgi apparatus localization of the membrane-bound and soluble forms of the sialytransferase, respectively, and that both regions may contain Golgi apparatus localization signals.     

The mucin box and signal/anchor sequence of rat neutral ceramidase recruit bacterial sphingomyelinase to the plasma membrane

Sphingolipid metabolites act as lipid mediators in various cellular events. We found that the mucin box and signal/anchor sequence of a rat neutral ceramidase recruit bacterial sphingomyelinase to the plasma membranes of mammalian cells. The mucin box-fused sphingomyelinase hydrolyzed cellular sphingomyelin efficiently to generate ceramide.     

Determinants for glycophospholipid anchoring of the Saccharomyces cerevisiae GAS1 protein to the plasma membrane.

A 125-kDa glycoprotein exposed on the surface of Saccharomyces cerevisiae cells belongs to a class of eucaryotic membrane proteins anchored to the lipid bilayer by covalent linkage to an inositol-containing glycophospholipid. We have cloned the gene (GAS1) encoding the 125-kDa protein (Gas1p) and found that the function of Gas1p is not essential for cell viability. The nucleotide sequence of GAS1 predicts a 60-kDa polypeptide with a cleavable N-terminal signal sequence, potential sites for N- and O-linked glycosylation, and a C-terminal hydrophobic domain. Determination of the anchor attachment site revealed that the C-terminal hydrophobic domain of Gas1p is removed during anchor addition. However, this domain is essential for addition of the glycophospholipid anchor, since a truncated form of the protein failed to become attached to the membrane. Anchor addition was also abolished by a point mutation affecting the hydrophobic character of the C-terminal sequence. We conclude that glycophospholipid anchoring of Gas1p depends on the integrity of the C-terminal hydrophobic domain that is removed during anchor attachment.     

Functional roles for fatty acylated amino-terminal domains in subcellular localization

Several membrane-associating signals, including covalently linked fatty acids, are found in various combinations at the N termini of signaling proteins. The function of these combinations was investigated by appending fatty acylated N-terminal sequences to green fluorescent protein (GFP). Myristoylated plus mono/dipalmitoylated GFP chimeras and a GFP chimera containing a myristoylated plus a polybasic domain were localized similarly to the plasma membrane and endosomal vesicles, but not to the nucleus. Myristoylated, nonpalmitoylated mutant chimeric GFPs were localized to intracellular membranes, including endosomes and the endoplasmic reticulum, and were absent from the plasma membrane, the Golgi, and the nucleus. Dually palmitoylated GFP was localized to the plasma membrane and the Golgi region, but it was not detected in endosomes. Nonacylated GFP chimeras, as well as GFP, showed cytosolic and nuclear distribution. Our results demonstrate that myristoylation is sufficient to exclude GFP from the nucleus and associate with intracellular membranes, but plasma membrane localization requires a second signal, namely palmitoylation or a polybasic domain. The similarity in localization conferred by the various myristoylated and palmitoylated/polybasic sequences suggests that biophysical properties of acylated sequences and biological membranes are key determinants in proper membrane selection. However, dual palmitoylation in the absence of myristoylation conferred significant differences in localization, suggesting that multiple palmitoylation sites and/or enzymes may exist.     

O-linked glycans mediate apical sorting of human intestinal sucrase-isomaltase through association with lipid rafts.

The plasma membrane of polarised epithelial cells is characterised by two structurally and functionally different domains, the apical and basolateral domains. These domains contain distinct protein and lipid constituents that are sorted by specific signals to the correct surface domain [1]. The best characterised apical sorting signal is that of glycophosphatidylinositol (GPI) membrane anchors [2], although N-linked glycans on some secreted proteins [3] and O-linked glycans [4] also function as apical sorting signals. In the latter cases, however, the underlying sorting mechanisms remain obscure. Here, we have analysed the role of O-glycosylation in the apical sorting of sucrase-isomaltase (SI), a highly polarised N- and O-glycosylated intestinal enzyme, and the mechanisms underlying this process. Inhibition of O-glycosylation by benzyl-N-acetyl-alpha-D-galactosaminide (benzyl-GalNAc) was accompanied by a dramatic shift in the sorting of SI from the apical membrane to both membranes. The sorting mechanism of SI involves its association with sphingolipid- and cholesterol-rich membrane rafts because this association was eliminated when O-glycosylation was inhibited by benzyl-GaINAc. The results demonstrate for the first time that O-linked glycans mediate apical sorting through association with lipid rafts.     

N-terminal motifs in some plant disease resistance proteins function in membrane attachment and contribute to disease resistance

To investigate the role of N-terminal domains of plant disease resistance proteins in membrane targeting, the N termini of a number of Arabidopsis and flax disease resistance proteins were fused to green fluorescent protein (GFP) and the fusion proteins localized in planta using confocal microscopy. The N termini of the Arabidopsis RPP1-WsB and RPS5 resistance proteins and the PBS1 protein, which is required for RPS5 resistance, targeted GFP to the plasma membrane, and mutation of predicted myristoylation and potential palmitoylation sites resulted in a shift to nucleocytosolic localization. The N-terminal domain of the membrane-attached Arabidopsis RPS2 resistance protein was targeted incompletely to the plasma membrane. In contrast, the N-terminal domains of the Arabidopsis RPP1-WsA and flax L6 and M resistance proteins, which carry predicted signal anchors, were targeted to the endomembrane system, RPP1-WsA to the endoplasmic reticulum and the Golgi apparatus, L6 to the Golgi apparatus, and M to the tonoplast. Full-length L6 was also targeted to the Golgi apparatus. Site-directed mutagenesis of six nonconserved amino acid residues in the signal anchor domains of L6 and M was used to change the localization of the L6 N-terminal fusion protein to that of M and vice versa, showing that these residues control the targeting specificity of the signal anchor. Replacement of the signal anchor domain of L6 by that of M did not affect L6 protein accumulation or resistance against flax rust expressing AvrL567 but removal of the signal anchor domain reduced L6 protein accumulation and L6 resistance, suggesting that membrane attachment is required to stabilize the L6 protein.     

The AATPAP sequence is a very efficient signal for O-glycosylation in CHO cells

The peptide signal sequence for protein O-glycosylation is not fully characterized, although a recent in vitro study proposed that the sequence motif, XTPXP, serves as a signal for mucin-type O-glycosylation. Here, we show that the AATPAP sequence acts as an efficient O-glycosylation signal, in vivo. A secreted fibroblast growth factor (secFGF) was used as a model to analyze glycosylation and its effects on the biological activity of FGF. Two constructs encoding [AATPAP]secFGF in which AATPAP was introduced at the N- or C-terminus of secFGF were constructed in a eukaryotic expression vector. [AATPAP]secFGF proteins were then expressed in Chinese hamster ovary (CHO) cells and secreted into the surrounding medium, primarily as modified forms sensitive to sialidase but not to peptide N-glycosidase F. The modifying groups were not seen when the AATPAP sequence was converted to AAAPAP or when [AATPAP]secFGF was expressed in mutant cells incapable of UDP-GalNAc biosynthesis. The results indicate that the modifying groups were mucin-type O-glycans and that the AATPAP served as an efficient O-glycosylation signal sequence. The O-glycosylated forms of [AATPAP]secFGF were as mitogenic toward human vascular endothelial cells as unmodified secFGF, suggesting that introduction of the signal into biologically active polypeptides is a promising approach with which O-glycosylation may be achieved without affecting original activity.     

Fusion of a cleavable signal peptide to the ectodomain of neutral endopeptidase (EC 3.4.24.11) results in the secretion of an active enzyme in COS-1 cells

Neutral endopeptidase (EC 3.4.24.11) is an integral membrane protein found at the plasma membrane of many cell types and is especially abundant at the apical "brush border" membrane of the kidney proximal tubules. The enzyme consists of a short amino-terminal cytosolic domain of 27 amino acids, a single hydrophobic sequence which is believed to be responsible for anchoring the enzyme in the plasma membrane, and a large extracellular domain containing the active site. This model is consistent with the proposed function of neutral endopeptidase, which is believed to play an important role in the inactivation of small regulatory peptides at the cell surface. Site-directed mutagenesis has allowed the identification of 1 glutamic acid and 2 histidine residues essential for catalysis. All are located near the COOH terminus of the protein. We do not know, however, whether other segments of the protein are involved in the structure of the active site. The exact role of the cytosolic and transmembrane domains is also unknown. In this report, we have induced the secretion of a soluble form of recombinant neutral endopeptidase in COS-1 cells by fusing in-frame, the cDNA encoding the signal peptide of a secreted protein (pro-opiomelanocortin) to the cDNA sequences of the complete ectodomain of neutral endopeptidase. Characterization of the secreted recombinant protein indicated that it has the same catalytic properties as the membrane-bound recombinant enzyme or as the enzyme extracted from kidney brush border membranes. Thus the extracellular domain alone is sufficient for conferring full catalytic activity to neutral endopeptidase.     

Spinach SoHXK1 is a mitochondria-associated hexokinase

Hexokinase, a hexose-phosphorylating enzyme, has emerged as a central enzyme in sugar-sensing processes. A few HXK isozymes have been identified in various plant species. These isozymes have been classified into two major groups; plastidic (type A) isozymes located in the plastid stroma and those containing a membrane anchor domain (type B) located mainly adjacent to the mitochondria, but also found in the nucleus. Of all the hexokinases that have been characterized to date, the only exception to this rule is a spinach type B HXK (SoHXK1) that, by means of subcellular fractionation, has been localized to the outer membrane of plastids. However, SoHXK1 has a membrane anchor domain that is almost identical to that of the other type B HXKs. To determine the localization of SoHXK1 enzyme by other means, we expressed SoHXK1::GFP fusion protein in tobacco and Arabidopsis protoplasts and compared its localization with that of the Arabidopsis AtHXK1::GFP fusion protein that shares a similar N-terminal membrane anchor domain. SoHXK1::GFP is localized adjacent to the mitochondria, similar to AtHXK1::GFP and all other previously examined type B HXKs. Proteomic analysis had previously identified AtHXK1 on the outside of the mitochondrial membrane. We, therefore, suggest that SoHXK1 enzyme is located adjacent to the mitochondria like the other type B HXKs that share the same N-terminal membrane anchor domain.     

Oligomerization of the sensory and motor neuron-derived factor prevents protein O-glycosylation

The sensory and motor neuron-derived factor (SMDF) is a neuregulin that promotes Schwann cell proliferation and differentiation. Hence, understanding axon myelination is important to unveil the mechanisms involved in SMDF biogenesis, membrane delivery, and compartmentalization. SMDF is a type II membrane protein expressed as two distinct polypeptides of approximately 40 and 83 kDa. Whether the 83-kDa polypeptide results from posttranslational modifications of the protein monomers or protein dimerization remains unknown. Here we have addressed this question and shown that the 83-kDa polypeptide is an O-glycosylated form of the protein. Deletion of the N-terminal domain fully abrogates the SMDF O-glycosylation, indicating that incorporation of O-glycans occurs in the intracellular domain of the protein. Notably, O-glycosylated forms are excluded from partitioning into lipid raft microdomains. In addition, we found that heterologously expressed SMDF monomers interact in intact living cells as evidenced from fluorescence resonance energy transfer of cyan fluorescent protein/yellow fluorescent protein.SMDF fusion proteins. A stepwise deletion approach demonstrated that SMDF self-association is primarily determined by its transmembrane segment. Notably, biochemical analysis revealed that SMDF multimers are exclusively composed of the 40-kDa polypeptide. Collectively, these findings indicate that the 40-kDa form corresponds to unmodified SMDF, which may be present as multimers, whereas the 83-kDa polypeptide is a monomeric O-glycosylated form of the protein. Furthermore, our observations imply a role for oligomerization as a potential modulator of the distribution in membrane domains and O-glycosylation of the protein.     

Transposition of domains between the M2 and HN viral membrane proteins results in polypeptides which can adopt more than one membrane orientation

The influenza A virus M2 polypeptide is a small integral membrane protein that does not contain a cleaved signal sequence, but is unusual in that it assumes the membrane orientation of a class I integral membrane protein with an NH2-terminal ectodomain and a COOH-terminal cytoplasmic tail. To determine the domains of M2 involved in specifying membrane orientation, hybrid genes were constructed and expressed in which regions of the M2 protein were linked to portions of the paramyxovirus HN and SH proteins, two class II integral membrane proteins that adopt the opposite orientation in membranes from M2. A hybrid protein (MgMH) consisting of the M2 NH2-terminal and membrane-spanning domains linked precisely to the HN COOH-terminal ectodomain was found in cells in two forms: integrated into membranes in the M2 topology or completely translocated across the endoplasmic reticulum membrane and ultimately secreted from the cell. The finding of a soluble form suggested that in this hybrid protein the anchor function of the M2 signal/anchor domain can be overridden. A second hybrid which contained the M2 NH2 terminus linked to the HN signal anchor and ectodomain (MgHH) was found in both the M2 and the HN orientation, suggesting that the M2 NH2 terminus was capable of reversing the topology of a class II membrane protein. The exchange of the M2 signal/anchor domain with that of SH resulted in a hybrid protein which assumed only the M2 topology. Thus, all these data suggest that the NH2-terminal 24 residues to M2 are important for directing the unusual membrane topology of the M2 protein. These data are discussed in relationship to the loop model for insertion of proteins into membranes and the role of charged residues as a factor in determining orientation.     

Association of Arabidopsis type-II ROPs with the plasma membrane requires a conserved C-terminal sequence motif and a proximal polybasic domain

Plant ROPs (or RACs) are soluble Ras-related small GTPases that are attached to cell membranes by virtue of the post-translational lipid modifications of prenylation and S-acylation. ROPs (RACs) are subdivided into two major subgroups called type-I and type-II. Whereas type-I ROPs terminate with a conserved CaaL box and undergo prenylation, type-II ROPs undergo S-acylation on two or three C-terminal cysteines. In the present work we determined the sequence requirement for association of Arabidopsis type-II ROPs with the plasma membrane. We identified a conserved sequence motif, designated the GC-CG box, in which the modified cysteines are flanked by glycines. The GC-CG box cysteines are separated by five to six mostly non-polar residues. Deletion of this sequence or the introduction of mutations that change its nature disrupted the association of ROPs with the membrane. Mutations that changed the GC-CG box glycines to alanines also interfered with membrane association. Deletion of a polybasic domain proximal to the GC-CG box disrupted the plasma membrane association of AtROP10. A green fluorescent protein fusion protein containing the C-terminal 25 residues of AtROP10, including its polybasic domain and GC-CG box, was primarily associated with the plasma membrane but a similar fusion protein lacking the polybasic domain was exclusively localized in the soluble fraction. These data provide evidence for the minimal sequence required for plasma membrane association of type-II ROPs in Arabidopsis and other plant species.     

Conversion of a Golgi apparatus sialyltransferase to a secretory protein by replacement of the NH2-terminal signal anchor with a signal peptide

The beta-galactoside alpha 2,6 sialyltransferase, an integral membrane protein localized to the trans-region of the Golgi apparatus, has been converted into a catalytically active secreted protein by the replacement of the NH2-terminal signal-anchor domain with the cleavable signal peptide of human gamma-interferon. Pulse-chase analysis of the wild type and recombinant proteins expressed in stably transfected Chinese hamster ovary cells showed that the wild type sialyltransferase (47 kDa) remained cell-associated. In contrast, the signal peptide-sialyltransferase fusion protein yielded an enzymatically active 41-kDa polypeptide which was secreted with a half-time of 2-3 h, consistent with cleavage of the signal peptide. The data indicate that the catalytic domain does not contain sufficient information for retention in the Golgi apparatus and that retention signals are likely to be found in the NH2-terminal 57 amino acids of the wild type enzyme.     

The signal for Golgi retention of bovine beta 1,4-galactosyltransferase is in the transmembrane domain.

The expression and localization of bovine beta 1,4-galactosyltransferase (Gal T) has been studied in mammalian cells transfected with Gal T cDNA constructs, and the role of the amino-terminal domains of Gal T in Golgi localization examined. Here we demonstrate that the transmembrane (signal/anchor) domain of bovine Gal T contains a positive Golgi retention signal. Bovine Gal T was characterized in transfected cells with anti-bovine Gal T antibodies, affinity-purified from a rabbit antiserum using a bacterial recombinant fusion protein. These affinity-purified antibodies recognized native bovine Gal T and showed minimum cross-reactivity with Gal T from non-bovine sources. Bovine Gal T cDNA was expressed, as active enzyme, transiently in COS-1 cells and stably in murine L cells, and the product was shown to be localized to the Golgi complex by immunofluorescence using the polypeptide-specific antibodies. A low level of surface bovine Gal T was also detected in the transfected L cells by flow cytometry. The removal of 18 of the 24 amino acids from the cytoplasmic domain of bovine Gal T did not alter the Golgi localization of the product transiently expressed in COS-1 cells or stably expressed in L cells. Both the full-length bovine Gal T and the cytoplasmic domain deletion mutant were N-glycosylated in the transfected L cells, indicating both proteins have the correct N(in)/C(out) membrane orientation. Deletion of both the cytoplasmic and signal/anchor domains of bovine Gal T and incorporation of a cleavable signal sequence resulted in a truncated soluble bovine Gal T that was rapidly secreted (within 1 h) from transfected COS-1 cells. Replacement of the signal/anchor domain of bovine Gal T with the signal/anchor domain of the human transferrin receptor resulted in the transport of the hybrid molecule to the cell surface of transfected COS-1 cells. Furthermore, a hybrid construct containing the signal/anchor domain of Gal T with ovalbumin was efficiently retained in the Golgi complex, whereas ovalbumin anchored to the membrane by the transferrin receptor signal/anchor was expressed at the cell surface of transfected COS-1 cells. Overall, these studies show that the hydrophobic, signal/anchor domain of Gal T is both necessary and sufficient for Golgi localization.     

Structural determinants required for apical sorting of an intestinal brush-border membrane protein

The distinct protein and lipid constituents of the apical and basolateral membranes in polarized cells are sorted by specific signals. O-Glycosylation of a highly polarized intestinal brush-border protein sucrase isomaltase is implicated in its apical sorting through interaction with sphingolipid-cholesterol microdomains. We characterized the structural determinants required for this mechanism by focusing on two major domains in pro-SI, the membrane anchor and the Ser/Thr-rich stalk domain. Deletion mutants lacking either domain, pro-SI(DeltaST) (stalk-free) and pro-SI(DeltaMA) (membrane anchor-free), were constructed and expressed in polarized Madin-Darby canine kidney cells. In the absence of the membrane anchoring domain, pro-SI(DeltaMA) does not associate with lipid rafts and the mutant is randomly delivered to both membranes. Therefore, the O-glycosylated stalk region is not sufficient per se for the high fidelity of apical sorting of pro-SI. Pro-SI(DeltaST) does not associate either with lipid rafts and its targeting behavior is similar to that of pro-SI(DeltaMA). Only wild type pro-SI containing both determinants, the stalk region and membrane anchor, associates with lipid microdomains and is targeted correctly to the apical membrane. However, not all sequences in the stalk region are required for apical sorting. Only O-glycosylation of a stretch of 12 amino acids (Ala(37)-Pro(48)) juxtapose the membrane anchor is required in conjunction with the membrane anchoring domain for correct targeting of pro-SI to the apical membrane. Other O-glycosylated domains within the stalk (Ala(49)-Pro(57)) are not sufficient for apical sorting. We conclude that the recognition signal for apical sorting of pro-SI comprises O-glycosylation of the Ala(37)-Pro(48) stretch and requires the presence of the membrane anchoring domain.     

Cloning and characterization of a 72-kDa inositol-polyphosphate 5-phosphatase localized to the Golgi network

The inositol-polyphosphate 5-phosphatase enzyme family removes the 5-position phosphate from both inositol phosphate and phosphoinositide signaling molecules. We have cloned and characterized a novel 5-phosphatase, which demonstrates a restricted substrate specificity and tissue expression. The 3.9-kb cDNA predicts for a 72-kDa protein with an N-terminal proline rich domain, a central 5-phosphatase domain, and a C-terminal CAAX motif. The 3. 9-kilobase mRNA showed a restricted expression but was abundant in testis and brain. Antibodies against the sequence detected a 72-kDa protein in the testis in the detergent-insoluble fraction. Indirect immunofluorescence of the Tera-1 cell line using anti-peptide antibodies to the 72-kDa 5-phosphatase demonstrated that the enzyme is predominantly located to the Golgi. Expression of green fluorescent protein-tagged 72-kDa 5-phosphatase in COS-7 cells revealed that the enzyme localized predominantly to the Golgi, mediated by the N-terminal proline-rich domain, but not the C-terminal CAAX motif. In vitro, the protein inserted into microsomal membranes on the cytoplasmic face of the membrane. Immunoprecipitated recombinant 72-kDa 5-phosphatase hydrolyzed phosphatidylinositol 3,4,5-trisphosphate and phosphatidylinositol 3, 5-bisphosphate, forming phosphatidylinositol 3,4-bisphosphate and phosphatidylinositol 3-phosphate, respectively. We propose that the novel 5-phosphatase hydrolyzes phosphatidylinositol 3,4, 5-trisphosphate and phosphatidylinositol 3,5-bisphosphate on the cytoplasmic Golgi membrane and thereby may regulate Golgi-vesicular trafficking.     

Tomato LeAGP-1 is a plasma membrane-bound, glycosylphosphatidylinositol-anchored arabinogalactan-protein

Arabinogalactan-proteins (AGPs) are a class of highly glycosylated, hydroxyproline-rich glycoproteins that function in plant growth and development. Tomato LeAGP-1 represents a major AGP expressed in cultured cells and plants. Based on cDNA and amino acid sequence analyses along with carbohydrate and other biochemical analyses, tomato LeAGP-1 is hypothesized to be a classical AGP localized to the plasma membrane via a glycosylphosphatidylinositol (GPI) anchor. Here, this hypothesis was tested and supported with the following experiments. First, tomato ( Lycopersicon esculentum , cv. UC82B) cotyledon protoplasts were isolated following cell wall digestion with cellulase and pectinase, and LeAGP-1 was immunolocalized to the plasma membrane with a LeAGP-1 antibody. Second, LeAGP-1 was shown to be a major AGP component in plasma membrane vesicles from tomato cv. Bonnie Best suspension-cultured cells by Western blot analysis with the LeAGP-1 antibody. Third, fluorescence microscopy of plasmolysed, transgenic tobacco ( Nicotiana tabacum BY-2) suspension-cultured cells expressing a green fluorescent protein (GFP)-LeAGP-1 fusion product demonstrated localization to the plasma membrane and Hechtian threads. Fourth, the GFP-LeAGP-1 fusion protein was present in plasma membrane preparations from these transgenic tobacco cells by Western blot analysis with a GFP antibody. Fifth, GFP-LeAGP-1 secreted into the culture media contained ethanolamine, presumably attached to the C-terminal amino acid residue, consistent with its processing and release from the plasma membrane. Thus, these data support the hypothesis that LeAGP-1 is localized to the plasma membrane via a GPI anchor and suggest possible roles for LeAGP-1 in cellular signalling and matrix remodelling.     

The juxtamembrane sequence of cytochrome P-450 2C1 contains an endoplasmic reticulum retention signal

The N-terminal signal anchor of cytochrome P-450 2C1 mediates retention in the endoplasmic reticulum (ER) membrane of several reporter proteins. The same sequence fused to the C terminus of the extracellular domain of the epidermal growth factor receptor permits transport of the chimeric protein to the plasma membrane. In the N-terminal position, the ER retention function of this signal depends on the polarity of the hydrophobic domain and the sequence KQS in the short hydrophilic linker immediately following the transmembrane domain. To determine what properties are required for the ER retention function of the signal anchor in a position other than the N terminus, the effect of mutations in the linker and hydrophobic domains on subcellular localization in COS1 cells of chimeric proteins with the P-450 signal anchor in an internal or C-terminal position was analyzed. For the C-terminal position, the signal anchor was fused to the end of the luminal domain of epidermal growth factor receptor, and green fluorescent protein was additionally fused at the C terminus of the signal anchor for the internal position. In these chimeras, the ER retention function of the signal anchor was rescued by deletion of three leucines at the C-terminal side of its hydrophobic domain; however, deletion of three valines from the N-terminal side did not affect transport to the cell surface. ER retention of the C-terminal deletion mutants was eliminated by substitution of alanines for glutamine and serine in the linker sequence. These data are consistent with a model in which the position of the linker sequence at the membrane surface, which is critical for ER retention, is dependent on the transmembrane domain.