Isolation of collagen binding proteins from embryonic chicken corneal epithelial cells

In the present paper, we report the isolation and characterization of embryonic corneal membrane glycoproteins that demonstrate specific affinity for collagen. Two collagen binding proteins have been isolated: a novel 70-kDa protein and a 47-kDa protein which is apparently similar to that reported by Kurkinen et al. (Kurkinen, M., Taylor, A., Garrels, J. I., and Hogan, B. (1984) J. Biol. Chem. 259, 5915-5922). Both proteins label metabolically with [35S]methionine and [3H] glucosamine. 125I iodination of cell surface proteins revealed that the two collagen binding proteins are expressed on the epithelial cell surface. The 70-kDa protein appears to be an integral membrane protein, whereas the 47-kDa protein can be removed from membranes by alkali treatment. The isolated proteins exhibit binding to native type IV collagen as well as heat-denatured type I collagen. It seems likely that we have isolated, at least in part, the cell surface receptor or receptor complex that binds collagen to the basal surface of epithelia.     

Identification and characterization of p63 (CKAP4/ERGIC-63/CLIMP-63), a surfactant protein A binding protein, on type II pneumocytes

Surfactant protein A (SP-A) binds to alveolar type II cells through a specific high-affinity cell membrane receptor, although the molecular nature of this receptor is unclear. In the present study, we have identified and characterized an SP-A cell surface binding protein by utilizing two chemical cross-linkers: profound sulfo-SBED protein-protein interaction reagent and dithiobis(succinimidylpropionate) (DSP). Sulfo-SBED-biotinylated SP-A was cross-linked to the plasma membranes isolated from rat type II cells, and the biotin label was transferred from SP-A to its receptor by reduction. The biotinylated SP-A-binding protein was identified on blots by using streptavidin-labeled horseradish peroxidase. By using DSP, we cross-linked SP-A to intact mouse type II cells and immunoprecipitated the SP-A-receptor complex using anti-SP-A antibody. Both of the cross-linking approaches showed a major band of 63 kDa under reduced conditions that was identified as the rat homolog of the human type II transmembrane protein p63 (CKAP4/ERGIC-63/CLIMP-63) by matrix-assisted laser desorption ionization and nanoelectrospray tandem mass spectrometry of tryptic fragments. Thereafter, we confirmed the presence of p63 protein in the cross-linked SP-A-receptor complex by immunoprobing with p63 antibody. Coimmunoprecipitation experiments and functional assays confirmed specific interaction between SP-A and p63. Antibody to p63 could block SP-A-mediated inhibition of ATP-stimulated phospholipid secretion. Both intracellular and membrane localized pools of p63 were detected on type II cells by immunofluorescence and immunobloting. p63 colocalized with SP-A in early endosomes. Thus p63 closely interacts with SP-A and may play a role in the trafficking or the biological function of the surfactant protein.     

ER membrane protein complex required for nuclear fusion

Diploid cells of the yeast Saccharomyces cerevisiae form after the mating of two haploid cells of the opposite mating type. After fusion of the two plasma membranes of the mating cells, a dinucleated cell forms initially in which the two haploid nuclei then rapidly fuse to form a single diploid nucleus. This latter event, called karyogamy, can be divided into two distinct steps: the microtubule-based movement that causes the two nuclei to become closely juxtaposed and the fusion of the nuclear membranes. For the membrane fusion step, one required component, the ER luminal protein Kar2p (BiP), has been identified. For topological reasons, however, it has been unclear how Kar2p could function in this role. Kar2p is localized to the luminal (i.e., noncytoplasmic) face of the ER membrane, yet nuclear fusion must initiate from the cytosolic side of the outer nuclear membrane or the ER membrane with which it is contiguous. There is both genetic and biochemical evidence that Kar2p interacts with Sec63p, an ER membrane protein containing both luminal and cytosolic domains that is involved in protein translocation across the membrane. We have isolated novel sec63 mutant alleles that display severe karyogamy defects. Disruption of the genes encoding other Sec63p-associated proteins (Sec71p and Sec72p) also results in karyogamy defects. A suppressor mutant (sos1-1) partially corrects the translocation defect but does not alleviate the karyogamy defect. sec61 and sec62 mutant alleles that cause similar or more severe protein translocation defects show no karyogamy defects. Taken together, these results suggest a direct role for Sec63p, Sec71p, and Sec72p in nuclear membrane fusion and argue against the alternative interpretation that the karyogamy defects result as an indirect consequence of the impaired membrane translocation of another component(s) required for the process. We propose that an ER/nuclear membrane protein complex composed of Sec63p, Sec71p, and Sec72p plays a central role in mediating nuclear membrane fusion and requires ER luminally associated Kar2p for its function.     

Purification of the rat hepatic alpha 2-macroglobulin receptor as an approximately 440-kDa single chain protein

alpha 2-Macroglobulin-trypsin complex (alpha 2M.T) and alpha 2M-methylamine bind in a Ca2+-dependent way to a 400- to 500-kDa receptor in rat and human liver membranes (Gliemann, J., Davidsen, O., and Moestrup, S. K. (1989) Biochim. Biophys. Acta 980, 326-332). Here we report the preparation of alpha 2M receptors from rat liver membranes solubilized in 3-[(3-cholamidopropyl) dimethylammonio]-1-propane sulfonic acid (CHAPS) dihydrate and incubated with Sepharose-immobilized alpha 2M-methylamine. The receptor preparation eluted with EDTA (pH 6.0) contained a protein larger than the 360-kDa alpha 2M (nonreducing sodium dodecyl sulfate-polyacrylamide gel electrophoresis) and some minor contaminants. The reduced large protein was about 440 kDa using reduced laminin (heavy chain: 400 kDa) as a standard. About 10 micrograms of receptor protein was obtained from 100 mg of liver membranes. The receptor preparation immobilized on nitrocellulose sheets bound 125I-alpha 2M.T, and the binding activity co-eluted with the 440-kDa protein. 125I-Labeled rat alpha 1-inhibitor-3 (alpha 1I3), a 200-kDa analogue of the alpha 2M subunit which binds to the alpha 2M receptors, was cross-linked to the 440-kDa protein. The receptor preparation was iodinated, and the 125I-labeled 440-kDa protein was isolated. It showed Ca2+-dependent saturable binding to alpha 2M-methylamine. In conclusion, we have purified the major hepatic alpha 2M receptor as an approximately 440-kDa single chain protein.     

Purification and subunit characterization of the rat liver endocytic hyaluronan receptor

The endocytic hyaluronan (HA) receptor of liver sinusoidal endothelial cells (LECs) is responsible for the clearance of HA and other glycosaminoglycans from the circulation in mammals. We report here for the first time the purification of this liver HA receptor. Using lectin and immuno-affinity chromatography, two HA receptor species were purified from detergent-solubilized membranes prepared from purified rat LECs. In nonreducing SDS-polyacrylamide gel electrophoresis (PAGE), these two proteins migrated at 175- and approximately 300 kDa corresponding to the two species previously identified by photoaffinity labeling of live cells as the HA receptor (Yannariello-Brown, J., Frost, S. J., and Weigel, P. H. (1992) J. Biol. Chem. 267, 20451-20456). These two proteins co-purify in a molar ratio of 2:1 (175:300), and both proteins are active, able to bind HA after SDS-PAGE, electrotransfer, and renaturation. After reduction, the 175-kDa protein migrates as a approximately 185-kDa protein and is not able to bind HA. The 300-kDa HA receptor is a complex of three disulfide-bonded subunits that migrate in reducing SDS-PAGE at approximately 260, 230, and 97 kDa. These proteins designated, respectively, the alpha, beta, and gamma subunits are present in a molar ratio of 1:1:1 and are also unable to bind HA when reduced. The 175-kDa protein and all three subunits of the 300-kDa species contain N-linked oligosaccharides, as indicated by increased migration in SDS-PAGE after treatment with N-glycosidase F. Both of the deglycosylated, nonreduced HA receptor proteins still bind HA.     

The structure of human retinol-binding protein (RBP) with its carrier protein transthyretin reveals an interaction with the carboxy terminus of RBP

Whether ultimately utilized as retinoic acid, retinal, or retinol, vitamin A is transported to the target cells as all-trans-retinol bound to retinol-binding protein (RBP). Circulating in the plasma, RBP itself is bound to transthyretin (TTR, previously referred to as thyroxine-binding prealbumin). In vitro one tetramer of TTR can bind two molecules of retinol-binding protein. However, the concentration of RBP in the plasma is limiting, and the complex isolated from serum is composed of TTR and RBP in a 1 to 1 stoichiometry. We report here the crystallographic structure at 3.2 A of the protein-protein complex of human RBP and TTR. RBP binds at a 2-fold axis of symmetry in the TTR tetramer, and consequently the recognition site itself has 2-fold symmetry: Four TTR amino acids (Arg-21, Val-20, Leu-82, and Ile-84) are contributed by two monomers. Amino acids Trp-67, Phe-96, and Leu-63 and -97 from RBP are flanked by the symmetry-related side chains from TTR. In addition, the structure reveals an interaction of the carboxy terminus of RBP at the protein-protein recognition interface. This interaction, which involves Leu-182 and Leu-183 of RBP, is consistent with the observation that naturally occurring truncated forms of the protein are more readily cleared from plasma than full-length RBP. Complex formation prevents extensive loss of RBP through glomerular filtration, and the loss of Leu-182 and Leu-183 would result in a decreased affinity of RBP for TTR.     

Reconstitution of the Saccharomyces cerevisiae DNA primase-DNA polymerase protein complex in vitro. The 86-kDa subunit facilitates but is not required for complex formation

The immunoaffinity-purified subunits of the yeast DNA primase-DNA polymerase protein complex and subunit-specific monoclonal antibodies were used to explore the structural relationships of the subunits in the complex. The reconstituted four-subunit complex (180-, 86-, 58-, and 49-kDa polypeptides) behaved as a single species, exhibiting a Stokes radius of 80 A and a sedimentation coefficient of 8.9 S. The calculated molecular weight of the reconstituted complex is 312,000. We infer that the stoichiometry of the complex is one of each subunit per complex. The complex has a prolate ellipsoid shape with an axial ratio of approximately 16. When the 180-kDa and DNA primase subunits were recombined in the absence of the 86-kDa subunit, a physical complex formed, as judged by immunoprecipitation of DNA primase activity and polypeptides with an anti-180-kDa monoclonal antibody. While the 86-kDa subunit readily forms a physical complex with the 180-kDa DNA polymerase catalytic subunit, we have not detected a complex containing 86-kDa and the DNA primase subcomplex (49- and 58-kDa subunits). The 86-kDa subunit was not required for DNA primase-DNA polymerase complex formation; the 180-kDa subunit and DNA primase heterodimer directly interact. However, the presence of the 86-kDa subunit increased the rate at which the DNA primase and 180-kDa polypeptides formed a complex and increased the total fraction of DNA primase activity that was associated with DNA polymerase activity. The observations demonstrate that the DNA primase p49.p58 heterodimer and the DNA polymerase p86.p180 heterodimer interact via the 180-kDa subunit. The four-subunit reconstituted complex was sufficient to catalyze the DNA chain extension coupled to RNA primer synthesis on a single-stranded DNA template, as previously observed in the conventionally purified complex isolated from wild type cells.     

Purification and characterization of an oxidase activating factor of 63 kilodaltons from bovine neutrophils

A 63-kDa protein, which behaves as an oxidase activating factor in bovine neutrophils, has been purified to electrophoretic homogeneity. The protein was isolated from the cytosol of resting bovine neutrophils after several steps, including ammonium sulfate precipitation and chromatography on AcA44, DE-52 cellulose, Mono Q, and Superose 12 in the presence of dithiothreitol. The oxidase activating potency of the protein was assayed with a cell-free system consisting of neutrophil membranes, GTP gamma S, arachidonic acid, and a complementary cytosolic fraction. The purification factor was 200 and the yield 3%. During the course of gel filtration on calibrated Superose 12, the 63-kDa protein eluted as a dimer. Its isoelectric point was 6.4 +/- 0.1. Antibodies raised in rabbits against the 63-kDa protein reacted with a protein of similar size in human neutrophils and in HL60 promyelocytic cells induced to differentiate into granulocytes. No immune reaction was observed in cytosol from undifferentiated HL60 cells, in extracts from bovine skeletal muscle, liver, and brain, or in cytosol prepared from neutrophils derived from a patient with an autosomal cytochrome b positive form of chronic granulomatous disease lacking the 67-kDa oxidase activating factor. Immunoblotting with the 63-kDa bovine protein antiserum demonstrated that activation of bovine neutrophil oxidase by phorbol myristate acetate induced the translocation of the 63-kDa protein from cytosol to the membrane.     

Apical polarity of Na,K-ATPase in retinal pigment epithelium is linked to a reversal of the ankyrin-fodrin submembrane cytoskeleton

In striking contrast to most other transporting epithelia (e.g., urinary or digestive systems), where Na,K-ATPase is expressed basolaterally, the retinal pigment epithelium (RPE) cells display Na,K-ATPase pumps on the apical membrane. We report here studies aimed to identify the mechanisms underlying this polarity "reversal" of the RPE Na,K-ATPase. By immunofluorescence on thin frozen sections, both alpha and beta subunits were localized on the apical surface of both freshly isolated rat RPE monolayers and RPE monolayers grown in culture. The polarity of the RPE cell is not completely reversed, however, since aminopeptidase, an apically located protein in kidney epithelia, was also found on the apical surface of RPE cells. We used subunit- and isoform-specific cDNA probes to determine that RPE Na,K-ATPase has the same isoform (alpha 1) as the one found in kidney. Ankyrin and fodrin, proteins of the basolateral membrane cytoskeleton of kidney epithelial cells known to be associated with the Na,K-ATPase (Nelson, W. J., and R. W. Hammerton. 1989. J. Cell Biol. 110:349-357) also displayed a reversed apical localization in RPE and were intimately associated to Na,K-ATPase, as revealed by cross-linking experiments. These results indicate that an entire membrane-cytoskeleton complex is assembled with opposite polarity in RPE cells. We discuss our observations in the context of current knowledge on protein sorting mechanisms in epithelial cells.     

Endoplasmic reticulum of rat liver contains two proteins closely related to skeletal sarcoplasmic reticulum Ca-ATPase and calsequestrin

Rat liver endoplasmic reticulum (ER) membranes were investigated for the presence of proteins having structural relationships with sarcoplasmic reticulum (SR) proteins. Western immunoblots of ER proteins probed with polyclonal antibodies raised against the 100-kDa SR Ca-ATPase of rabbit skeletal muscle identified a single reactive protein of 100 kDa. Also, the antibody inhibited up to 50% the Ca-ATPase activity of isolated ER membranes. Antisera raised against the major intraluminal calcium binding protein of rabbit skeletal muscle SR, calsequestrin (CS), cross-reacted with an ER peptide of about 63 kDa, by the blotting technique. Stains-All treatment of slab gels showed that the cross-reactive peptide stained metachromatically blue, similarly to SR CS. Two-dimensional electrophoresis (Michalak, M., Campbell, K. P., and MacLennan, D. H. (1980) J. Biol. Chem. 255, 1317-1326) of ER proteins showed that the CS-like component of liver ER, similarly to skeletal CS, fell off the diagonal line, as expected from the characteristic pH dependence of the rate of mobility of mammalian CS. In addition, the CS-like component of liver ER was released from the vesicles by alkaline treatment and was found to be able to bind calcium, by a 45Ca overlay technique. From these findings, we conclude that a 100-kDa membrane protein of liver ER is the Ca-ATPase, and that the peripheral protein in the 63-kDa range is closely structurally and functionally related to skeletal CS.     

Epidermal growth factor dependent phosphorylation of a 35-kilodalton protein in placental membranes

In human placental membranes isolated in the presence of ethylenediaminetetraacetic acid (EDTA), epidermal growth factor (EGF) stimulated the [gamma-32P]ATP-dependent phosphorylation of tyrosine residues on the 170-kilodalton (kDa) EGF receptor and on a 35-kDa protein. The initial rate of phosphorylation of these proteins in the presence of EGF was 5.2 and 3.5 nmol of phosphate min-1 (mg of receptor protein)-1, and this was approximately 10- and 6-fold higher than the basal rate, respectively. Half-maximal phosphorylation of both proteins occurred at about 2.5 nM EGF. In the presence of p-nitrophenyl phosphate, EGF stimulated the phosphorylation of the 35-kDa protein but not the EGF receptor, suggesting that hormone-stimulated autophosphorylation of the receptor/kinase was not required for kinase activation. The 35-kDa protein exists in two forms: (1) 35Keluate, which was associated with the membrane in the presence of Ca2+ but was eluted with EDTA, and (2) 35Kmemb, which was not eluted from membranes with EDTA. Both forms were immunologically related to a 35-kDa protein previously isolated from A431 cells. Antiserum against the 35-kDa protein also reacted with a protein with an apparent size of 66 kDa that was phosphorylated in an EGF-dependent manner. In phosphorylation reactions performed in the presence of Mg2+, Ca2+ was required for phosphorylation of the 35Keluate form, but Ca2+ was not required for phosphorylation of the 35Kmemb form. Phosphorylation appears to change the membrane-binding properties of the 35Kmemb form because 32P-labeled 35Kmemb could be eluted from the membrane by EDTA.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cellular distribution of type I and type II receptors for transforming growth factor-beta

Affinity labeling of target cells for transforming growth factor-beta (TGF beta) by cross-linking with 125I-TGF beta via disuccinimidyl suberate or by the photoreactive analogue 4-azidobenzoyl-125I-TGF beta has revealed the presence of multiple TGF beta receptor forms. Two distinct types of TGF beta receptors can be distinguished based on structural analysis of the 125I-TGF beta-labeled species by peptide mapping. Type I TGF beta receptors include the 280-kilodalton labeled receptor form previously found to be the subunit of a disulfide-linked TGF beta receptor complex. (Massagué, J. (1985) J. Biol. Chem. 260, 7059-7066), as well as a 65-kDa labeled receptor form present in all cell lines examined, and a 130-140-kDa labeled receptor form detected only in 3T3-L1 cells. The 280-kDa form is the major TGF beta receptor species in most cell lines examined, but is apparently absent in rat skeletal muscle myoblasts. Type I TGF beta receptors bind TGF beta with an apparent Kd of 50-500 pM. Type II TGF beta receptors include an 85-kDa labeled receptor form present in all mammalian cells examined and a 110-kDa labeled receptor form present in chick embryo fibroblasts. Type II TGF beta receptors bind TGF beta with an apparent Kd of about 50 pM. Except for the 280-kDa type I TGF beta receptor form, none of the TGF beta receptor forms described here is found as part of a disulfide-linked receptor complex. All the TGF beta receptor forms described here behave as intrinsic membrane proteins exposed on the surface of intact cells.     

A cleavable affinity biotinylating agent reveals a retinoid binding role for RPE65

Retinal pigment epithelial (RPE) membranes contain the full biochemical apparatus capable of processing all-trans-retinol (vitamin A) into 11-cis-retinal, the visual chromophore. As many of these proteins are integral membrane proteins and resistant to traditional methods of identification, alternate methods of identifying these proteins are sought. The approach described here involves affinity biotinylation with alkali cleavable linkers. A vitamin A containing affinity-labeling haloacetate is described which facilitates the identification of retinoid binding proteins (RBPs). Treatment of crude bovine RPE membranes with (3R)-3-[boc-lys(biotinyl)-O]-all-trans-retinol chloroacetate 1 in the low micromolar range led to the specific labeling of RPE65 and lecithin retinol acyltransferase (LRAT). Only RPE65 is labeled at 5 microM 1 at 4 degrees C. Labeled RPE65 was readily isolated by binding the labeled protein to avidin-containing beads, followed by cleavage of the protein from the beads at pH 11. Trypsin digestion of RPE65 modified by 1, followed by mass spectrometry, demonstrates that C231 and C448 are alkylated by 1. These studies validate the approach that was used, and furthermore demonstrate that RPE65, a major membrane-associated protein of the RPE, is a RBP.     

Affinity labeling of the galactose/N-acetylgalactosamine-specific receptor of rat hepatocytes: preferential labeling of one of the subunits

The galactose/N-acetylgalactosamine-specific receptor (also known as asialoglycoprotein receptor) of rat hepatocytes consists of three subunits, one of which [43 kilodalton (kDa)] exists in a greater abundance (up to 70% of total protein) over the two minor species (52 and 60 kDa). When the receptor on the hepatocyte membranes was photoaffinity labeled with an 125I-labeled high-affinity reagent [a triantennary glycopeptide containing an aryl azide group on galactosyl residues; Lee, R. T., & Lee, Y. C. (1986) Biochemistry 25, 6835-6841], the labeling occurred mainly (51-80%) on one of the minor bands (52 kDa). Similarly, affinity-bound, N-acetylgalactosamine-modified lactoperoxidase radioiodinated the same 52-kDa band preferentially. In contrast, both the photoaffinity labeling and lactoperoxidase-catalyzed iodination of the purified, detergent-solubilized receptor resulted in a distribution of the label that is comparable to the Coomassie blue staining pattern of the three bands; i.e., the 43-kDa band was the major band labeled. These and other experimental results suggest that the preferential labeling of the minor band and inefficient labeling of the major band on the hepatocyte membrane resulted from a specific topological arrangement of these subunits on the membranes. We postulate that in the native, membrane-bound state of the receptor, the 52-kDa minor band is topologically prominent, while the major (43 kDa) band is partially masked. This partial masking may result from a tight packing of the receptor subunits on the membranes to form a lattice work [Hardy, M. R., Townsend, R. R., Parkhurst, S. M., & Lee, Y. C. (1985) Biochemistry 24, 22-28].     

A new trophoblast-derived growth factor from human placenta: purification and receptor identification

This paper describes the identification and characterization of a new peptide growth factor. The peptide was isolated from trophoblastic brush border membranes of human placenta. The purified preparation was homogeneous and consisted of a single polypeptide of Mr 34 000 with a pI of about 6.0. This peptide stimulated DNA replication in cultured fibroblasts. The following association was seen between activity and protein: During DEAE-cellulose chromatography, both the 34-kilodalton (kDa) protein and the mitogenic activity displayed identical binding and salt dependence of elution. Nondenaturing electrophoresis at pH 8.3 revealed a comigration of the 34-kDa protein and the DNA replication stimulatory activity. Identical electrophoretic mobilities were displayed for both activity and protein at pH 7.0. These results demonstrate that the preparation is homogeneous and show that growth factor activity is intrinsic to the 34-kDa polypeptide. Binding of the 125I-labeled 34-kDa mitogen to target fibroblastic cells was specific; i.e., nanomolar concentrations of the unlabeled 34-kDa protein competed effectively with the labeled protein, whereas a variety of well-characterized growth factors and hormones were unable to compete even at micromolar levels. Thus the 34-kDa protein interacts with target cells through highly specific surface receptors. Chemical cross-linking techniques were used to investigate the identity of the receptor for the 34-kDa mitogen. Cross-linking of fibroblastic cells containing bound 125I-labeled 34-kDa protein generated a radiolabeled complex of 86 kDa in all four cell types examined.(ABSTRACT TRUNCATED AT 250 WORDS)     

A tip-high gradient of a putative plasma membrane SNARE approximates the exocytotic gradient in hyphal apices of the fungus Neurospora crassa

Antibodies to the Saccharomyces cereviseae plasma membrane t-SNARE Sso2p identify a putative 39-kDa homologue in Neurospora crassa. The 39-kDa protein is enriched in plasma membrane (PM) and occurred with other membranes. It is extractable by detergent, but not chaotropic or alkali agents, suggesting membrane insertion. Immunoprecipitation with anti-Sso2p coprecipitated a approximately 100-kDa, Mg(+)-ATP-sensitive band with the 39-kDa protein, suggesting a ternary SNARE complex. Affinity-purified anti-Sso2p gave hyphal staining patterns most consistent with protein localization on both the PM and intracellular exocytotic apical wall vesicles. The PM staining in hyphal apices formed a tip-high gradient, not as steep as that predicted by the "hyphoid equation," but closer to published gradients of cell wall matrix deposition. We conclude that the t-SNAREs are transported to the PM on the apical vesicles, but their tip-high gradient alone is insufficient to explain the vesicle fusion gradient in growing tips.     

Mammalian Sec61 is associated with Sec62 and Sec63

In yeast, efficient protein transport across the endoplasmic reticulum (ER) membrane may occur co-translationally or post-translationally. The latter process is mediated by a membrane protein complex that consists of the Sec61p complex and the Sec62p-Sec63p subcomplex. In contrast, in mammalian cells protein translocation is almost exclusively co-translational. This transport depends on the Sec61 complex, which is homologous to the yeast Sec61p complex and has been identified in mammals as a ribosome-bound pore-forming membrane protein complex. We report here the existence of ribosome-free mammalian Sec61 complexes that associate with two ubiquitous proteins of the ER membrane. According to primary sequence analysis both proteins display homology to the yeast proteins Sec62p and Sec63p and are therefore named Sec62 and Sec63, respectively. The probable function of the mammalian Sec61-Sec62-Sec63 complex is discussed with respect to its abundance in ER membranes, which, in contrast to yeast ER membranes, apparently lack efficient post-translational translocation activity.     

Disruption of a putative SH3 domain and the proline-rich motifs in the 53-kDa substrate of the insulin receptor kinase does not alter its subcellular localization or ability to serve as a substrate

The recently identified 53-kDa substrate of the insulin receptor family was further characterized in several retroviral-generated stable cell lines overexpressing the wild type and various mutant forms of the protein. To facilitate the study of its subcellular localization in NIH3T3 cells overexpressing insulin receptor, a myc epitope-tag was added to the carboxy terminus of the 53-kDa protein. Like the endogenous protein in Chinese hamster ovary cells, the expressed myc-tagged 53-kDa protein was found partially in the particulate fraction and was tyrosine phosphorylated in insulin-stimulated cells. Immunofluorescence studies showed for the first time that a fraction of the 53-kDa protein was localized to the plasma membrane. Confocal microscopy of cells double-labeled with antibodies to the insulin receptor and the myc epitope showed the two proteins co-localize at the plasma membrane at the level of light microscopy. Further analyses of the protein sequence of the 53-kDa substrate revealed the presence of a putative SH3 domain and two proline-rich regions, putative binding sites for SH3 and WW domains. Disruption of these three motifs by the introduction of previously characterized point mutations did not affect the membrane localization of the 53-kDa protein, its ability to serve as substrate of the insulin receptor, or its colocalization with the insulin receptor, suggesting these domains are not important in the subcellular targeting of the protein and instead may function in the interaction with subsequent signaling proteins. J. Cell. Biochem. 68:139–150, 1998. © 1998 Wiley-Liss, Inc.     

Neuropeptide Y. Differential binding to rat intestinal laterobasal membranes

Neuropeptide Y (NPY), a neurotransmitter contained within intrinsic nerves of the small intestine, inhibits secretion when added to the serosal side of intestinal mucosa mounted in Ussing chambers. Using NPY radiolabeled with IODO-GEN, lactoperoxidase, or the Bolton-Hunter reagent, we have localized high affinity NPY receptors to the serosal laterobasal membranes of the rat intestinal epithelial cell, isolated according to a recently described protocol that minimizes contamination with endoplasmic reticulum, Golgi, and brush-border membranes. In addition, certain species of radiolabeled NPY, including those labeled with IODO-GEN at the tyrosine residue 36, also demonstrated an ability to bind to brush-border membranes. These receptors were specific for NPY since the homologous peptides, pancreatic polypeptide and peptide YY, were less efficient than NPY in inhibiting the membrane binding of radiolabeled NPY. By cross-linking NPY to its receptor with either disuccinimidyl suberate or dithiobis(succinimidyl propionate) and analyzing the resulting complexes on sodium dodecyl sulfate-polyacrylamide gel electrophoresis followed by radioautography, we identified two NPY receptor species with molecular sizes of 52-59 kDa and 37-39 kDa. The 37-39-kDa species further possesses a disulfide bond which may attach it to a separate approximately 5-kDa subunit, as evidenced by retarded migration in the absence of the reducing agent dithiothreitol. The intestinal NPY receptor is slightly smaller than the rat brain receptor previously characterized using similar techniques. The localization of NPY receptors on laterobasal membranes is consistent with previous anatomic and physiologic findings, and their identification by cross-linking techniques will constitute the basis for detailed characterization.