Biosynthesis and intracellular movement of the melanosomal membrane glycoprotein gp75, the human b (brown) locus product

A 75-kDa melanosomal glycoprotein (gp75) is the product of a gene that maps to the b (brown) locus, a genetic locus that determines coat color in the mouse. The b locus is conserved (88% identity) between mouse and human. The mouse monoclonal antibody TA99 was used to study the biosynthesis and processing of gp75. gp75 was synthesized as a 55-kDa polypeptide, glycosylated by addition and processing of five or more Asnlinked carbohydrate chains through the cis and trans Golgi, and transported to melanosomes as a mature 75kDa form. Synthesis and processing of gp75 was rapid (T_1/2 < 30 min), and early steps in processing were required for efficient export of gp75 to melanosomes. Fully processed mature gp75 was quite stable (T_1/2 = 22–24 h) in the melanosome. Digestion of high-mannose carbohydrate chains with endo-β-N-acetylglucosaminidase H revealed two alternative processed forms of gp75 that differed in the number or composition of complex-type carbohydrate chains. The rate of synthesis and movement through intracellular membrane compartments was the same for both glycosylated forms. Studies with inhibitors of steps in oligosaccharide processing showed that alternative forms of gp75 were generated during trimming reactions by mannosidase IA/IB and that further maturation resulted in the two mature forms of gp75. We propose that the kinetics of biosynthesis and processing reflect events in the biogenesis and maturation of melanosomes.     

The order of processing events in mouse mammary tumor virus envelope protein maturation: implications for the location of the glucocorticoid-regulated step.

Treatment of the W7MG1 mouse T lymphoma cell line with glucocorticoid stimulates directly or indirectly two observable steps in the processing of mouse mammary tumor virus (MMTV) envelope glycoprotein precursor Pr74: cleavage of Pr74 to yield the mature glycoprotein products gp52 and gp33, and processing of the N-linked oligosaccharides to endoglycosidase H (endo H)-resistant forms found on the mature products but not on the precursor. Therefore, the primary hormone-regulated event in this pathway must occur at or before the point where MMTV envelope proteins become endo H resistant. Pulse-chase analyses identified a novel endo H-resistant 80-kDa species (designated gp80) as a processing intermediate. Therefore, in contrast to conclusions drawn for the envelope proteins of several other retroviruses, proteolytic cleavage of MMTV envelope proteins occurs after acquisition of endo H resistance. Also, proteolytic cleavage cannot be the primary hormone-regulated step. Second, inhibition of mannosidase II by the drug swainsonine did not prevent Pr74 from being proteolytically processed, thus demonstrating that conversion of oligosaccharide chains from endo H-sensitive to -resistant forms was not a prerequisite for proteolytic cleavage. Therefore, the requisite hormone-regulated event in MMTV glycoprotein processing must precede both acquisition of endo H resistance and proteolytic cleavage. This places the regulated event in the endoplasmic reticulum or early Golgi.     

Epitope mapping of the melanosomal matrix protein gp100 (PMEL17): rapid processing in the endoplasmic reticulum and glycosylation in the early Golgi compartment

Melanosomes, specific organelles produced only by melanocytes, undergo a unique maturation process that involves their transition form amorphous rounded vesicles to fibrillar ellipsoid organelles, during which they move from the perinuclear to the distal areas of the cells. This depends upon the trafficking and processing of gp100 (also known as Pmel17 and the silver protein), a protein of great interest, because it elicits immune responses in melanoma patients but in which specific function(s) remains elusive. In this study, we have used biochemical and immunochemical approaches to more critically assess the synthesis, processing, glycosylation, and trafficking of gp100. We now report that gp100 is processed and sorted in a manner distinct from other melanosomal proteins (such as tyrosinase, Tyrp1 and Dct) and is predominantly delivered directly to immature melanosomes following its rapid processing in the endoplasmic reticulum and cis-Golgi. Following its arrival, gp100 is cleaved at the amino and at the carboxyl termini in a series of specific steps that result in the reorganization of immature melanosomes to the fibrillar mature melanosomes. Once this structural reorganization occurs, melanogenic enzymes begin to be targeted to the melanosomes, which are then competent to synthesize melanin pigment.     

Characterization of oligosaccharide chains on mouse mammary tumor virus envelope proteins and the implications for the mechanism of their glucocorticoid regulated processing

Glucocorticoid hormone is required for complete posttranslational processing of the glycosylated mouse mammary tumor virus envelope precursor, Pr74env in the murine T-lymphosarcoma cell line, W7MG1. Metabolic labeling studies with [35S]methionine, [3H]galactose, and [3H]mannose, combined with enzymatic digestion analyses with a variety of endoglycosidases, demonstrated that both proteolytic processing and N-linked oligosaccharide maturation depended, either directly or indirectly, on glucocorticoid action. Pr74 is found in both control and hormone-treated cells. In both cases Pr74 molecules carry high mannose and/or hybrid, but not complex, oligosaccharide chains with very little or no sialic acid. When cells are grown with glucocorticoid, Pr74 is converted to gp52 and gp33 with greatly increased efficiency, and these mature glycoproteins carry complex oligosaccharides containing sialic acid. No O-linked carbohydrate was detected on any of these species. According to this evidence, the glucocorticoid-regulated step in this pathway must occur at or before the final mannose trimming step in the Golgi that is required for formation of complex carbohydrate chains.     

Processing of the gp55-116 envelope glycoprotein complex (gB) of human cytomegalovirus.

The processing pathway of the major envelope glycoprotein complex, gp55-116 (gB), of human cytomegalovirus was studied using inhibitors of glycosylation and endoglycosidases. The results of these studies indicated that the mature gp55-116 is synthesized by the addition of both simple and complex N-linked sugars to a nonglycosylated precursor of estimated Mr 105,000. In a rapid processing step, the Mr 105,000 precursor is glycosylated to a protein of Mr 150,000 (gp150) which contains only endoglycosidase H-sensitive sugar linkages. The gp150 is then processed relatively slowly to a Mr 165,000 to 170,000 species (gp165-170), which is then cleaved to yield the mature gp55-116. Monensin prevented the final processing steps of the gp150, including cleavage, suggesting that transport through the Golgi apparatus is required for complete processing. Digestion of the intracellular forms of this complex as well as the virion forms confirmed the above findings and indicated that the mature virion form of gp55 contains 8,000 daltons of N-linked sugars. The virion gp116 contains some 52,000 to 57,000 daltons of N-linked carbohydrates and approximately 5,000 daltons of O-linked sugars.     

Site-directed mutagenesis and expression of PC2 in microinjected Xenopus oocytes.

The biosynthesis and post-translational maturation of PC2, a neuroendocrine-specific Kex2-like endoprotease, following expression in Xenopus oocytes is described. The initial translation product was a 75-kDa membrane-associated protein which was released from the oocytes as a glycosylated 71-kDa protein. During extended chase periods, the extracellular 71-kDa protein was converted to a mature 68-kDa product. A deletion mutant lacking a putative COOH-terminal amphipathic helix was still membrane-associated, suggesting that this domain was not essential for attachment of PC2 to membranes. Two putative proregion cleavage site mutants were also constructed. Conversion of the 75-kDa peptide to the 71-kDa peptide involved cleavage at the sequence Lys-Arg-Arg-Arg (amino acids 78-81), since mutation of this sequence to Lys-Val-Arg-Leu resulted in the secretion of the 75-kDa peptide. Extracellular conversion of the 71-kDa peptide to the 68-kDa peptide involved cleavage at the sequence Arg-Lys-Lys-Arg (amino acids 106-109), since deletion of this tetrabasic sequence resulted in secretion of the 71-kDa peptide without further conversion to the 68-kDa form. Finally, a mutation which changed a catalytically important Asp to Asn did not affect processing of proPC2. These results may be relevant to our understanding of mechanisms in the intracellular sorting and maturation of proPC2 in neuroendocrine cells.     

Biosynthesis pathway of gp90MEL-14, the mouse lymph node-specific homing receptor

The mouse lymph node specific homing receptor gp90MEL-14 is a 95-kDa molecular mass ubiquitinated cell surface molecule involved in the binding of lymphocytes to high endothelial venules in peripheral lymph nodes. The molecule is thought to consist of a core protein to which ubiquitin side chains are covalently bound. Recently we cloned the cDNA encoding the core protein; this cDNA clone encodes for a polypeptide with an estimated molecular mass of 37 kDa. We have studied the biosynthesis of gp90MEL-14 in an effort to explain the difference in molecular mass between the core protein and the 95-kDa mature molecule. Pulse labeling experiments show a rapid synthesis of a 70-kDa precursor form that contains high-mannose N-linked oligosaccharides. On processing of the high-mannose oligosaccharides into complex N-linked oligosaccharides, the precursor matures in a single step into the 95-kDa form. Experiments using deglycosylating enzymes and inhibitors of N-linked glycosylation demonstrate that the molecular mass of deglycosylated gp90MEL-14 is 45 kDa; extensive N-linked glycosylation is responsible for the difference in molecular mass with the mature 95-kDa form. The core protein molecular weight of in vitro transcribed and translated gp90MEL-14 cDNA is consistent with the estimated molecular mass of 37 kDa, calculated from the cDNA sequence of the core protein, and 8 to 10 kDa less than the protein molecular mass of gp90MEL-14 translated in vivo in the presence of tunicamycin (45 kDa). Inasmuch as we have ruled out glycosylation as accounting for this discrepancy, this is consistent with the addition of one ubiquitin moiety to the core protein during biosynthesis. Limited proteolysis confirms the similarity between in vitro transcribed gp90MEL-14 cDNA and the tunicamycin form of gp90MEL-14.     

Subcellular localization of glycoproteins encoded by the viral oncogene v-fms

The McDonough strain of feline sarcoma virus encodes a polyprotein that is cotranslationally glycosylated and proteolytically cleaved to yield transforming glycoproteins specified by the viral oncogene v-fms. The major form of the glycoprotein (gp120fms) contains endoglycosidase H-sensitive, N-linked oligosaccharide chains lacking fucose and sialic acid, characteristic of glycoproteins in the endoplasmic reticulum. Kinetic and steady-state measurements showed that most gp120fms molecules were not converted to mature forms containing complex carbohydrate moieties. Fixed-cell immunofluorescence confirmed that the majority of v-fms-coded antigens were internally sequestered in transformed cells. Dual-antibody fluorescence performed with antibodies to intermediate filaments (IFs) showed that the IFs of transformed cells were rearranged, and their distribution coincided with that of v-fms-coded antigens. No specific disruption of actin cables was observed. The v-fms gene products cofractionated with IFs isolated from virus-transformed cells and reassociated with IFs self-assembled in vitro. A minor population of v-fms-coded molecules (gp140fms) acquired endoglycosidase H-resistant, N-linked oligosaccharide chains containing fucose and sialic acid residues, characteristic of molecules processed in the Golgi complex. Some gp140fms molecules were detected at the plasma membrane and were radiolabeled by lactoperoxidase-catalyzed iodination of live transformed cells. We suggest that v-fms-coded molecules are translated as integral transmembrane glycoproteins, most of which are inhibited in transport through the Golgi complex to the plasma membrane.     

The 43-kDa glycoprotein from the human pathogen Paracoccidioides brasiliensis and its deglycosylated form: excretion and susceptibility to proteolysis

Biochemical properties of the concanavalin A-binding 43-kDa glycoprotein (gp43) of Paracoccidioides brasiliensis and its deglycosylated form were compared. Deglycosylation was achieved by treatment with trifluoromethanesulfonic acid, endoglycosidase H, N-glycanase, or metabolically, by growing cells with tunicamycin. The resulting antigen in all cases had Mr 38,000, and probably derived from the gp43 by loss of N-linked high-mannose oligosaccharide chains. The presence of galactopyranose units in the carbohydrate chains was suggested by antigen binding to peanut lectin. Pulse and chase experiments using [35S]methionine metabolic labeling of P. brasiliensis growing in the presence of tunicamycin showed that the N-linked chains of gp43 are not required for antigen secretion. The 38-kDa antigen was more susceptible than the native antigen to the action of papain and pronase, thus indicating a protective role of the carbohydrate moiety against proteolysis. Both forms are equally resistant to endogenous proteases at neutral pH. The gp43, itself, has a proteolytic activity at pH 5-6, but not at neutral pH. Deglycosylation with endoglycosidase H or tunicamycin preserved epitopes in the 38-kDa molecule reactive with (a) antibodies from patients with paracoccidioidomycosis, or rabbit immunized with the gp43 and (b) mouse monoclonal antibodies against the gp43 antigen. The present results provide a basis for the understanding of diagnostic reactions and fungal virulence involving the gp43 exocellular antigen of P. brasiliensis.     

IDS Transfer from Overexpressing Cells to IDS-Deficient Cells

Iduronate sulfatase (IDS) is responsible for mucopolysaccharidosis type II, a rare recessive X-linked lysosomal storage disease. The aim of this work was to test the ability of overexpressing cells to transfer IDS to deficient cells. In the first part of our work, IDS processing steps were compared in fibroblasts, COS cells, and lymphoblastoid cell lines and shown to be identical: the two precursor forms (76 and 90 kDa) were processed by a series of intermediate forms to the 55- and 45-kDa mature polypeptides. Then IDS transfer to IDS-deficient cells was tested either by incubation with cell-free medium of overexpressing cells or by coculture. Endocytosis and coculture experiments between transfected Lβ and deleted fibroblasts showed that IDS transfer occurred preferentially by cell-to-cell contact as IDS precursors are poorly secreted by transfected Lβ. The 76- and 62-kDa IDS polypeptides transferred to deleted fibroblasts were correctly processed to the mature 55- and 45-kDa forms. Lβ were not able to internalize the 90-kDa phosphorylated precursor forms excreted in large amounts in the medium of overexpressing fibroblasts. Enzyme transfer occurred only by cell-to-cell contact, but the precursor forms transferred in Lβ after cell-to-cell contact were not processed. This absence of maturation was probably due to a mistargeting of IDS precursors in these cells.     

Biosynthesis and processing of lysosomal cathepsin L in primary cultures of rat hepatocytes

The biosynthesis and proteolytic processing of lysosomal cathepsin L was studied using in vitro translation system and in vivo pulse-chase analysis with [35S]methionine and [32P]phosphate in primary cultures of rat hepatocytes. Messenger RNA prepared from membrane-bound but not free polysomes directed the synthesis of a primary translation product of an immunoprecipitable 37.5-kDa cathepsin L in vitro. The 37.5-kDa form was converted to the 39-kDa form when translated in the presence of dog pancreas microsomes. During pulse-chase experiments with [35S]methionine in cultured rat hepatocytes, cathepsin L was first synthesized as a 39-kDa protein, presumably the proform, after a short time of labeling, and was subsequently processed into the mature forms of 30 and 25 kDa in the cell. On the other hand, considerable amounts of the proenzyme were found to be secreted into the culture medium without further proteolytic processing during the chase. The precursor and mature enzymes were N-glycosylated with high-mannose-type oligosaccharides, and the proenzyme molecule contained phosphorylated oligosaccharides. The effects of tunicamycin and chloroquine were also investigated. In the presence of tunicamycin, a 36-kDa unglycosylated polypeptide appeared in the cell and this protein was exclusively secreted from the cells without undergoing proteolytic processing. These results suggest that cathepsin L is initially synthesized on membrane-bound polysomes as a 37.5-kDa prepropeptide and that the cotranslational cleavage of the 1.5-kDa signal peptide and the core glycosylation convert the precursor to the 39-kDa proform, which is subsequently processed to the mature form during biosynthesis. Thus, the biosynthesis and secretion of lysosomal cathepsin L in rat hepatocytes seem to be analogous to those of the major excreted protein of transformed mouse fibroblasts [S. Gal, M. C. Willingham, and M. M. Gottesman (1985) J. Cell Biol. 100, 535-544] and the mouse cysteine proteinase of activated macrophages [D.A. Portnoy, A. H. Erickson, J. Kochan, J. V. Ravetch, and J. C. Unkeless (1986) J. Biol. Chem. 261, 14697-14703].     

Glycosylation is necessary for the correct folding of human immunodeficiency virus gp120 in CD4 binding.

Conflicting results have been reported regarding the role of carbohydrate on human immunodeficiency virus (HIV) envelope glycoprotein gp120 in CD4 receptor binding. Glycosylated, deglycosylated, and nonglycosylated forms of HIV type 1 (HIV-1) and HIV-2 gp120s were used to examine CD4 receptor-binding activity. Nonglycosylated forms of gp120 generated either by deletion of the signal sequence of HIV-1 gp120 or by synthesis in the presence of tunicamycin failed to bind to CD4. In contrast, highly mannosylated gp120 bound to soluble CD4 molecules well. Enzymatic removal of carbohydrate chains from glycosylated gp120 by endoglycosidase H or an endoglycosidase F/N glycanase mixture had no effect on the ability of gp120 to bind CD4. An experiment which measured the ability of gp120 to bind to CD4 as an assay of the proper conformation of gp120 showed that carbohydrate chains on gp120 are not required for the interaction between gp120 and CD4 but that N-linked glycosylation is essential for generation of the proper conformation of gp120 to provide a CD4-binding site.     

A novel intermediate in processing of murine leukemia virus envelope glycoproteins. Proteolytic cleavage in the late Golgi region.

The intracellular processing of the murine leukemia virus envelope glycoprotein precursor Pr85 to the mature products gp70 and p15e was analyzed in the mouse T-lymphoma cell line W7MG1. Kinetic (pulse-chase) analysis of synthesis and processing, coupled with endoglycosidase (endo H) and neuraminidase digestions revealed the existence of a novel high molecular weight processing intermediate, gp95, containing endo H-resistant terminally glycosylated oligosaccharide chains. In contrast to previously published conclusions, our data indicate that proteolytic cleavage of the envelope precursor occurs after the acquisition of endo H-resistant chains and terminal glycosylation and thus after the mannosidase II step. In the same W7MG1 cell line, the type and order of murine leukemia virus envelope protein processing events was identical to that for the mouse mammary tumor virus envelope protein. Interestingly, complete mouse mammary tumor virus envelope protein processing requires the addition of glucocorticoid hormone, whereas murine leukemia virus envelope protein processing occurs constitutively in these W7MG1 cells. We propose that all retroviral envelope proteins share a common processing pathway in which proteolytic processing is a late event that follows acquisition of endo H resistance and terminal glycosylation.     

Posttranslational processing of human lysosomal acid beta-glucosidase: a continuum of defects in Gaucher disease type 1 and type 2 fibroblasts.

The major processing steps in the maturation of the lysosomal hydrolase, acid beta-glucosidase, were examined in fibroblasts from normal individuals and from patients with types 1 and 2 Gaucher disease. In pulse-chase studies with normal fibroblasts, remodeling of N-linked oligosaccharides resulted in the temporal appearance of three molecular-weight forms of acid beta-glucosidase. An initial 64-kDa form, containing high mannose-type oligosaccharide side chains, was processed quantitatively, within 24 h, to a sialylated 69-kDa form. During the subsequent 96 h, some of the 69-kDa form is processed to 59 kDa. Glycosidase digestion studies revealed that the increase in the apparent molecular weight of the normal enzyme from 64 kDa to 69 kDa resulted primarily from the addition to sialic acid residues in the Golgi apparatus. The polypeptide backbone of both the 64-kDa and 69-kDa forms was 55.3 kDa. Processing of acid beta-glucosidase in fibroblasts from three of four type 1 (nonneuronopathic) Ashkenazi Jewish Gaucher disease patients was nearly normal. With fibroblasts from one Ashkenazi Jewish and three non-Jewish type 1 as well as from two type 2 (acute neuronopathic) Gaucher disease patients, only a 64-kDa form of acid beta-glucosidase was detected. Inefficient and incomplete processing to the 69-kDa form was found in one type 2 cell line (GM2627). These results indicate that no firm correlation exists between the type or degree of abnormal processing of acid beta-glucosidase in fibroblasts and the phenotype of Gaucher disease.     

A novel mechanism of lysosomal acid sphingomyelinase maturation: requirement for carboxyl-terminal proteolytic processing

Acid sphingomyelinase (aSMase) catalyzes the hydrolysis of sphingomyelin (SM) to form the bioactive lipid ceramide (Cer). Notably, aSMase exists in two forms: a zinc (Zn(2+))-independent lysosomal aSMase (L-SMase) and a Zn(2+)-dependent secreted aSMase (S-SMase) that arise from alternative trafficking of a single protein precursor. Despite extensive investigation into the maturation and trafficking of aSMase, the exact identity of mature L-SMase has remained unclear. Here, we describe a novel mechanism of aSMase maturation involving C-terminal proteolytic processing within, or in close proximity to, endolysosomes. Using two different C-terminal-tagged constructs of aSMase (V5, DsRed), we demonstrate that aSMase is processed from a 75-kDa, Zn(2+)-activated proenzyme to a mature 65 kDa, Zn(2+)-independent L-SMase. L-SMase is recognized by a polyclonal Ab to aSMase, but not by anti-V5 or anti-DsRed antibodies, suggesting that the C-terminal tag is lost during maturation. Furthermore, indirect immunofluorescence staining demonstrated that mature L-SMase colocalized with the lysosomal marker LAMP1, whereas V5-aSMase localized to the Golgi secretory pathway. Moreover, V5-aSMase possessed Zn(2+)-dependent activity suggesting it may represent the common protein precursor of S-SMase and L-SMase. Importantly, the 65-kDa L-SMase, but not V5-aSMase, was sensitive to the lysosomotropic inhibitor desipramine, co-fractionated with lysosomes, and migrated at the same M(r) as partially purified human aSMase. Finally, three aSMase mutants containing C-terminal Niemann-Pick mutations (R600H, R600P, ΔR608) exhibited defective proteolytic maturation. Taken together, these results demonstrate that mature L-SMase arises from C-terminal proteolytic processing of pro-aSMase and suggest that impaired C-terminal proteolysis may lead to severe defects in L-SMase function.     

Intracellular processing, glycosylation, and cell surface expression of human metapneumovirus attachment glycoprotein

The biosynthesis and posttranslational processing of human metapneumovirus attachment G glycoprotein were investigated. After pulse-labeling, the G protein accumulated as three species with molecular weights of 45,000, 50,000, and 53,000 (45K, 50K, and 53K, respectively). N-Glycosidase digestion indicated that these forms represent the unglycosylated precursor and N-glycosylated intermediate products, respectively. After an appropriate chase, these three naive forms were further processed to a mature 97K form. The presence of O-linked sugars in mature G protein was confirmed by O-glycanase digestion and lectin-binding assay using Arachis hypogaea (peanut agglutinin), an O-glycan-specific lectin. In addition, in the O-glycosylation-deficient cell line (CHO ldlD cell), the G protein could not be processed to the mature form unless the exogenous Gal and GalNAc were supplemented, which provided added evidence supporting the O-linked glycosylation of G protein. The maturation of G was completely blocked by monensin but was partially sensitive to brefeldin A (BFA), suggesting the O-linked glycosylation of G initiated in the trans-Golgi compartment and terminated in the trans-Golgi network. Enzymatic deglycosylation analysis confirmed that the BFA-G was a partial mature form containing N-linked oligosaccharides and various amounts of O-linked carbohydrate side chains. The expression of G protein at the cell surface could be detected by indirect immunofluorescence staining assay. Furthermore, cell surface immunoprecipitation displayed an efficient intracellular transport of G protein.     

Role of glycosylation in the processing of newly translated insulin proreceptor in 3T3-L1 adipocytes

A procedure was developed for the immunoprecipitation of glycosylated and nonglycosylated forms of the insulin receptor and its precursors without prior purification using lectins. 3T3-L1 adipocytes were labeled with [35S]methionine after which 35S-labeled receptor polypeptides were specifically immunoprecipitated and characterized by sodium dodecyl sulfatepolyacrylamide gel electrophoresis. The first 35S-polypeptide detected was a 190-kDa glycosylated proreceptor which was rapidly (t1/2 approximately equal to 15 min) processed to a 210-kDa intermediate. The latter precursor was more slowly (t1/2 approximately equal to 2 h) proteolytically processed to 125-kDa (alpha') and 83-kDa (beta') precursors of the mature alpha- and beta-receptor subunits. Immediately prior to insertion into the plasma membrane, i.e. about 3 h after translation, the alpha'- and beta'-precursor polypeptides were converted to the mature 135-kDa alpha- and 95-kDa beta-receptor subunits. The characteristics of the oligosaccharide moieties of the receptor precursors and products were investigated. The 210-kDa precursor and its two products, the 125-kDa alpha'- and 83-kDa beta'-species, and the mature alpha- and beta-receptor subunits bind tightly to wheat germ lectin, whereas the 190-kDa proreceptor species is not bound. Upon incubation with endoglycosidase H, both the 210- and 190-kDa species are converted to a 180-kDa species. The 125-kDa alpha'- and 83-kDa beta'-species are also cleaved by endoglycosidase H, being reduced in size to 97 and 79 kDa, respectively. Based on their sensitivity to endoglycosidase H and insensitivity to neuraminidase, the oligosaccharide chains of the receptor precursors (190, 210, 125, and 83 kDa) do not contain terminal sialic acid (or other capping sugars). However, near the time of insertion into the plasma membrane, capping of the alpha'- and beta'-species by sialic acid occurs, giving rise to the mature 135-kDa alpha- and 95-kDa beta-receptor subunits, which are partially endoglycosidase H-resistant and neuraminidase-sensitive. When 3T3-L1 adipocytes are treated with tunicamycin, a 180-kDa proreceptor aglycopolypeptide is synthesized which is incapable of undergoing further processing and proteolytic cleavage to the alpha- and beta (or alpha'- and beta'-)-subunits. The 180-kDa species, which appears to be the aglyco-form of hte 190-kDa proreceptor generated by endoglycosidase H, is resistant to trypsin in the intact cell and apparently has not reached the cell surface. Thus, the oligosaccharide moieties of the insulin receptor precursor are crucial for proper processing, intracellular translocation, and formation of functionally competent insulin re     

Prion protein biosynthesis in scrapie-infected and uninfected neuroblastoma cells.

Numerous studies have indicated that a modified proteinase K-resistant form of an endogenous brain protein, prion protein (PrP), is associated with scrapie infection in animals. This scrapie-associated PrP modification appears to occur posttranslationally in brain, but its molecular nature is not known. To learn about the normal PrP biosynthesis and whether it is altered by scrapie infection in vitro, we did metabolic labeling experiments with uninfected and scrapie-infected mouse neuroblastoma tissue culture cells. Pulse-chase labeling experiments indicated that, in both cell types, two major PrP precursors of 28 and 33 kilodaltons (kDa) were processed to mature 30- and 35- to 41-kDa forms. Endoglycosidase H, tunicamycin, and phospholipase treatments revealed that the 28- and 33-kDa precursors resulted from the addition of high-mannose glycans to a 25-kDa polypeptide containing a phosphatidylinositol moiety and that maturation of the precursors involved the conversion of the high-mannose glycans to hybrid or complex glycans. Treatments of the live cells with trypsin and phosphatidylinositol-specific phospholipase C indicated that the mature PrP species were expressed solely on the cell surface, where they were anchored by covalent linkage to phosphatidylinositol. Once on the cell surface, the major PrP forms had half-lives of 3 to 6 h. No differences in PrP biosynthesis were observed between the scrapie-infected versus uninfected neuroblastoma cells.     

Assignment of the human TYRP (brown) locus to chromosome region 9p23 by nonradioactive in situ hybridization.

The TYRP (brown) locus determines pigmentation and coat color in the mouse. The human homolog of the TYRP locus has been recently identified and shown to encode a 75-kDa transmembrane melanosomal glycoprotein called gp75. The gp75 glycoprotein is homologous to tyrosinase, an enzyme involved in the synthesis of melanin, forming a family of tyrosinase-related proteins. A genomic clone of human gp75 was used to map the human TYRP locus to chromosome 9, region 9p23, by nonradioactive fluorescent in situ hybridization. Specificity of hybridization was tested with a genomic fragment of human tyrosinase that mapped to a distinct site on 11q21. The 9p region has been reported to be nonrandomly altered in human melanoma, suggesting a role for the region near the TYRP locus in melanocyte transformation.     

Biosynthetic and glycosylation events of the IL-6 receptor β-Subunit,gp130

It is now recognized that the β-subunit of the interleukin-6 (IL-6) receptor, also known as gp130, is a common signal transducer shared by other cytokines, including ciliary neurotrophic factor, leukemia inhibitor factor, oncostatin M, and IL-11. In this study, the biosynthesis and glycosylation of hepatic gp130 were investigated using a specific polyclonal antibody to the 287 amino acid cytoplasmic domain of gp130. Immunoprecipitation and metabolic labeling experiments demonstrate, in addition to a mature surface expressed gp130, the presence of a major immature form of the molecule within the cell. The immature form can shift to become a functional gp130 only after being terminally glycosylated. The kinetics of gp130 maturation and surface expression were determined. When both forms of gp130 are deglycosylated the resulting core peptides migrate to identical positions in a denatured protein gel, indicating that the principal difference between the two forms resides in the extent of their glycosylation. IL-6 and other members of this cytokine family activate only the mature form, demonstrating its location at the membrane surface. Protein and mRNA turnover studies reveal gp130 to be a stable, slowly renewing population under nonstimulated conditions. These findings provide novel information on the intracellular events leading to the expression of this critically important signal transducing protein.