Fast axonal transport of tyrosine sulfate-containing proteins: Preferential routing of sulfoproteins toward nerve terminals

The presence of a subset of fast-transported proteins containing sulfate while lacking carbohydrate residues [Stone et al. (1983). J. Neurochem. 41:1085-1089] was confirmed by two-dimensional gel electrophoretic analysis of individual fast-transported proteins double-labeled with 35SO4 and [3H]mannose. Analysis by high-pressure liquid chromatography revealed that the sulfate moieties of these "sulfoproteins" are linked to tyrosine residues. Separation of fast-transported 35SO4-labeled proteins delivered to local regions of axon from proteins en route toward terminal regions demonstrated, on the basis of acid lability of tyrosine-bound sulfate, that the sulfoproteins were localized preferentially in the wavefront of fast-transported proteins. Analysis of individual sulfoproteins confirmed differential transport in that sulfoproteins were present at threefold greater amount in the wavefront than in material off-loaded to local regions of the axon. By contrast, nonsulfated species of molecular weights similar to those of the sulfoproteins were detected in nearly equal amounts in both regions of the transport profile. Treatment of nerve segments containing total 35SO4-labeled fast-transported proteins with sodium carbonate led to solubilization of half the protein-bound sulfate. Exposure of the solubilized proteins to mild acid resulted in the release of approximately 80% of the 35SO4 associated with this fraction. Two-dimensional gel patterns displaying carbonate releasable or nonreleasable fractions are consistent with the most abundantly labeled sulfoproteins being transported within membrane-bound organelles. In terms of apparent destination and subcellular compartmentalization, the sulfoproteins meet critical requirements for consideration as secretable fast-transported proteins.     

Fast-Transported Glycoproteins and Nonglycosylated Proteins Contain Sulfate

35SO4-labeled fast-transported proteins of bullfrog dorsal root ganglion neurons were separated by two-dimensional gel electrophoresis, and their mobilities were compared to similar species labeled with [3H]mannose or [3H]fucose. Fluorography revealed regions of poorly resolved, high molecular weight material, likely to represent sulfated proteoglycans, as well as many well resolved spots that corresponded in mobility to individual [35S]methionine-labeled fast-transported proteins. The majority of these well resolved spots appeared as "families," previously identified as glycoproteins based on their labeling with sugars. Thus, sulfate can be a contributor to the carbohydrate side-chain charge that underlies microheterogeneity. The most heavily 35SO4-labeled species, however, corresponded to fast-transported proteins that were not labeled by either sugar. The relative acid labilities of 35SO4 associated with individual species cut from the gel confirmed the assignments of these spots as glycoproteins or nonglycoproteins. A group of spots intermediate in their acid lability was also detected, suggesting that some proteins may contain sulfate linked to carbohydrate as well as to amino acid residues.     

In vivo and in vitro tyrosine sulfation of a membrane glycoprotein

A431 cells incorporate 35SO4 into a protein of Mr 61,000 (P61). We examined sulfation of P61 by cells (in vivo) and by a cell-free system (in vitro) which requires only addition of A431 cell membranes and a 3'-phosphoadenosine 5'-phospho[35S]sulfate-generating system prepared from Krebs ascites cells. Sulfate is found exclusively in the form of tyrosine SO4 by two-dimensional high voltage electrophoresis following Pronase digestion. Endoglycosidase F digestion reduces the Mr by 2,000 but does not release the sulfate, indicating that P61 is a glycoprotein but that sulfate is not incorporated into the carbohydrate. Sulfated P61 is not found in the medium from cultured cells and remains associated with the membrane fraction following cell lysis. Treatment of membranes with 0.4 M NaCl, 0.3 M KCl, 15 mM EDTA, or pH 11.0 does not release sulfated P61. P61 is solubilized by Triton X-114 treatment of membranes and partitions into the detergent phase upon warming. Based on these characteristics, we conclude that P61 is an integral membrane protein. Trypsin digestion experiments with intact cells suggest that sulfated P61 is predominantly located in the plasma membrane. This is the first example of an integral membrane protein which is sulfated on tyrosine. The properties of the sulfation reaction are distinct from those reported for secreted proteins and are consistent with the possibility that this modification occurs at the plasma membrane rather than in the Golgi.     

Complex-type N-linked oligosaccharides of gp120 from human immunodeficiency virus type 1 contain sulfated N-acetylglucosamine.

The major envelope glycoproteins gp120 and gp41 of human immunodeficiency virus type 1, the causative agent for human AIDS, contain numerous N-linked oligosaccharides. We report here our discovery that N-acetylglucosamine residues within the complex-type N-linked oligosaccharides of both gp120 and its precursor, gp160, are sulfated. When human Molt-3 cells persistently infected with human T-cell leukemia virus IIIB were metabolically radiolabeled with 35SO4, gp160, gp120, and to some extent gp41 were radiolabeled. The 35SO4-labeled oligosaccharides were quantitatively released by N-glycanase treatment and were bound by immobilized Ricinus communis agglutinin I, a lectin that binds to terminal beta-galactosyl residues. The kinetics of release of sulfate upon acid hydrolysis from 35SO4-labeled gp120 indicate that sulfation occurs in a primary sulfate ester linkage. Methylation analysis of total glycopeptides from Molt-3 cells metabolically radiolabeled with [3H]glucosamine demonstrates that sulfation occurs at the C-6 position of N-acetylglucosamine. Fragmentation of the gp120-derived 35SO4-labeled glycopeptides by treatment with hydrazine and nitrous acid and subsequent reduction generated galactosyl-anhydromannitol-6-35SO4, which is the expected reaction product from GlcNAc-6-sulfate within a sulfated lactosamine moiety. Charge analysis of the [3H]galactose- and [3H]glucosamine-labeled glycopeptides from gp120 and gp160 indicates that approximately 14% of the complex-type N-linked oligosaccharides are sulfated.     

Sulfation of porcine parathyroid secretory protein I. Detection of tyrosine sulfate

Secretory Protein I (SP-I) is an acidic glycoprotein that is stored and co-secreted with parathormone by parathyroid glands. It has been found to be chemically similar, if not identical, to chromogranin A of the adrenal medulla and to be present in most endocrine cells. In the present study, 35SO4 was shown to be incorporated into SP-I and several other proteins of porcine parathyroid tissue incubated in vitro. The predominant sulfated species secreted to the medium was SP-I. Up to 20% of the tyrosine residues in secreted SP-I were labeled with 35SO4. Both the cellular and secreted forms migrated on sodium dodecyl sulfate gels as a pair of proteins with apparent molecular weights of 82,000 and 78,000. The 82-kDa protein could be converted to the 78-kDa species by treatment with neuraminidase. Sulfate exists in SP-I as tyrosine sulfate based on the identification of this amino acid by thin layer electrophoresis following alkaline hydrolysis. Extracellular Ca2+ (3 mM) greatly suppressed the secretion of 35SO4-labeled SP-I without affecting the intracellular sulfation of the molecule or the secretion of a minor sulfated protein unrelated to SP-I. The ratio of incorporated 35SO4 to 3H-amino-acid was greater in secreted SP-I than in tissue SP-I, suggesting that much sulfation of this protein occurred during or just before secretion.     

Subsets of Axonally Transported and Periaxonal Polypeptides Are Released from Regenerating Nerve

Using two-dimensional polyacrylamide gel electrophoresis to analyze proteins, we have found subsets of periaxonal and fast-transported axoplasmic proteins that are released in vitro from regenerating sciatic nerve into a surrounding bath. Of the fast-transported proteins that are released from nerve, there is a subset of at least five polypeptides that appears in greater relative abundance in the bath than in the nerve. Some of these released, fast-transported proteins are glycosylated. Several periaxonally synthesized polypeptides are released in significantly greater amounts from regenerating nerve, and of these polypeptides, two are released in greater amounts from nerve only at regions of regeneration or distal to regeneration. These released polypeptides do not represent the most abundant of the locally synthesized proteins. The released, fast-transported and periaxonal proteins may play a role in intercellular signaling or in modulation of the extracellular environment during nerve regeneration.     

Recombinant human fibrinogen and sulfation of the gamma' chain

Human fibrinogen and the homodimeric gamma'-chain-containing variant have been expressed in BHK cells using cDNAs coding for the alpha, beta, and gamma (or gamma') chains. The fibrinogens were secreted at levels greater than 4 micrograms (mg of total cell protein)-1 day-1 and were biologically active in clotting assays. Recombinant fibrinogen containing the gamma' chain incorporated 35SO4 into its chains during biosynthesis, while no incorporation occurred in the protein containing the gamma chain. The identity of the sulfated gamma' chain was verified by its ability to form dimers during clotting. In addition, carboxypeptidase Y digestion of the recombinant fibrinogen containing the gamma' chain released 96% of the 35S label from the sulfated chain, and the radioactive material was identified as tyrosine O-sulfate. These results clarify previous findings of the sulfation of tyrosine in human fibrinogen.     

Cell surface changes correlated with density-dependent growth inhibition. Glycosaminoglycan metabolism in 3T3, SV3T3, and con A selected revertant cells.

A 35SO4-labeling/chromatography technique has been developed which facilitates quantitation of sulfated glycosaminoglycan (GAG) synthesis in mammalian cell cultures. The technique has been used to compare sulfated GAG biosynthesis, degradation, and turnover in three related cell lines with differing degrees of density-dependent inhibition of growth in vitro (Balb/c 3T3, SV3T3, and SV3T3 revertant cells). Viral transformation of Balb 3T3 cells is accompanied by a 2-5-fold decrease in cell associated sulfated GAG. SV3T3 revertant cells, which show partial reversion to low saturation density in vitro, show a 2.5-8-fold increase in cell-associated sulfated GAG compared to the parental SV3T3 cells from which they were selected. In addition, the distribution of 35SO4 and [3H]glucosamine among the different GAG species produced by SV3T3 revertant cells reverts so that it is similar to the distribution characteristic of untransformed 3T3 cells rather than SV3T3 cells. Mild trypsin treatment of 35SO4-labeled cells removed 68-84% of the cellular sulfated GAG, suggesting that at least this proportion of the total cellular sulfated GAG was located at the cell periphery. Removal of 35SO4-labeled cells from the Petri dish with a Ca2+ selective chelating agent revealed a fraction of the sulfated GAG that remained tightly bound to the Petri dish. A higher proportion of the total cell-associated sulfated GAG remained attached to the Petri dish in cultures of untransformed and revertant cells compared to that present in cultures of transformed cells. A role for sulfated GAG in density-dependent growth inhibition of fibroblast cultures is proposed and discussed in the light of the data obtained.     

Secretion of sulfated and nonsulfated forms of parathyroid chromogranin A (secretory protein-I)

Chromogranin A (secretory protein-I) is an acidic, sulfated glycoprotein found in secretory granules of most endocrine cells but not in exocrine or epithelial cells. Parathyroid chromogranin A is sulfated on tyrosine residues, whereas adrenal chromogranin A appears to be sulfated mainly on oligosaccharide residues. Chromogranin B, on the other hand, is tyrosine-sulfated in the bovine adrenal whereas this protein is absent from the parathyroid. The role of this tissue- or species-specific sulfation of chromogranin is not known. Tyrosine sulfation is a common post-translational modification of proteins in the exocytotic pathway and has been suggested to play a role in the sorting or intracellular transport of secretory proteins. To test this, porcine parathyroid tissue slices were metabolically labeled with 35SO4 and [3H]Lys, and the tissue and incubation medium analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, immunoblotting, and immunoprecipitation with chromogranin A-specific antiserum or by radioimmunoassay for parathormone. Secretion of total and 3H-labeled chromogranin A was about 3- and 7-fold higher, respectively, at 0.5 mM than at 3.0 mM Ca2+, and secretion of 35SO4-labeled chromogranin A was 67-fold higher. This indicates that either sulfated chromogranin A is directed primarily to the Ca2+-regulated pathway or that sulfation occurs following sorting to this pathway. Sodium chlorate (1-10 mM) inhibited sulfation in a dose-dependent manner by up to 95% but it had no effect on the onset or rate of chromogranin A secretion. These data indicate that regulated secretion of parathyroid chromogranin A does not require sulfation of tyrosine residues.     

Estrogen-dependent and progesterone-arrested synthesis and secretion of sulfated glycoproteins in luminal epithelia of rat uteri.

1. 35SO4 administered intraperitoneally was specifically incorporated into a glycopeptide component separated by electrophoresis of the glycosaminoglycan fraction prepared from the uterine epithelia (luminal), as well as the uterine fluid of ovariectomized rats treated with estradiol-17 beta, in contrast to the rats without estrogen treatment. 2. The epithelial cells of uteri isolated from estrogen-treated ovariectomized rats incorporated 35SO4 in vitro into at least two macromolecular components. The larger molecular weight component (sodium dodecyl sulfate polyacryl-amide gel electrophoresis and/or gel filtration) labelled with 35S was observed in both the cytosol and particulate fractions, whereas the smaller molecular weight component labelled with 35S was found only in the particulate fraction. 35SO4 was also incorporated into two macromolecular components in the incubation medium, similarly to the particulate fraction. A 35 SO4-labelled glycopeptide similar to that from the epithelial particulate fraction and the incubation medium, and not from the epithelial cytosol fraction. 3. Progesterone, in contrast to estrogen, did not stimulate the sulfated blycoprotein synthesis. Moreover, progesterone administered together with or after estrogen-administration completely arrested the estrogen-dependent synthesis and secretion of the sulfated glycoproteins in the uterine epithelia.     

Occurrence of sulfate in an asparagine-linked complex oligosaccharide of chicken adipose lipoprotein lipase

After adipocytes were labeled with Na2[35SO4], immunoadsorbed with immobilized antilipoprotein lipase, and subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and fluorography, a labeled band was identified at 59,700 daltons, the molecular mass of chicken lipoprotein lipase (LPL). Excess unlabeled LPL prevented the immunoadsorption of this labeled species, hence the labeled species was determined to be LPL. Digestion of LPL with endo-beta-N-acetylglucosaminidase H (Endo H) caused a shift in mobility of LPL in SDS-PAGE with no loss of radioactivity, whereas digestion with glycopeptidase F resulted in removal of 99% of the radioactivity. Adipocytes cultured with Trans35S-label and tunicamycin produced an LPL species of 52,000 daltons, but tunicamycin abolished the incorporation of 35SO4 into LPL. This established that 35SO4 was incorporated into an N-linked oligosaccharide of LPL. Endo H digestion of pulse-chase labeled LPL revealed the presence of two complex and one high mannose-type N-linked oligosaccharides. A single 35SO4-labeled tryptic peptide was isolated by reverse phase chromatography. The amino acid sequence of the peptide established that the 35SO4 oligosaccharide is conjugated at Asn-45. Behavior of the 35SO4-labeled oligosaccharide on concanavalin A-agarose, sequential exoglycosidase digestion, and chemical analysis of the 35SO4 oligosaccharide confirms that this moiety is of the complex type. Sequential exoglycosidase digestion, thin layer chromatography of the released monosaccharides, and the use of glycosylation inhibitors established that the sulfated sugar is a core N-acetylglucosamine (GlcNAc). The data show that chicken LPL contains two complex and one high mannose N-linked oligosaccharides and that 35SO4 is incorporated into LPL on a GlcNAc residue of a complex oligosaccharide located at Asn-45.     

Association of heparan sulfate proteoglycan and laminin with the cytoskeleton in rat liver

Rats were injected with 35SO4 and after 2 h their livers were removed and used to prepare a detergent-insoluble cytoskeleton fraction. Spectrin, cytokeratins, and actin were major protein components of the isolated cytoskeletons. The cytoskeleton fraction accounted for approximately 14% of the total trichloroacetic acid-insoluble 35SO4 radioactivity incorporated into the liver. The cytoskeleton-associated radioactivity was present in a single species of macromolecule. This molecule was not present to a significant extent in the detergent-soluble fraction containing the cell supernatant and dissolved membrane proteins. Further characterization revealed the cytoskeleton-associated molecule was a heparan sulfate proteoglycan: it was eluted from a Sepharose CL-4B column under denaturing conditions at Kav = 0.4; following mild alkaline hydrolysis the radioactivity was eluted at a Kav = 0.7; when this material was subjected to nitrous acid hydrolysis all of the radioactivity was eluted near the column included volume. The isolated cytoskeletons contained attached nuclei. Pure nuclei isolated without associated cytoskeletal elements contained less than 1% of the total liver trichloroacetic acid-insoluble 35SO4 radioactivity and no detectable heparan sulfate proteoglycan. These results suggested that other matrix proteins might be associated with the liver cytoskeleton. When the subcellular distribution of laminin was monitored by immunostaining proteins transferred to nitrocellulose, laminin was detected exclusively in the cytoskeleton fraction. These results provide evidence for an association between extracellular connective tissue proteins and intracellular structural proteins.     

Sulfated N-linked oligosaccharides in mammalian cells. III. Characterization of a pancreatic carcinoma cell surface glycoprotein with N- and O-sulfate esters on asparagine-linked glycans

In the preceding two papers, we described two new classes of sulfated N-linked oligosaccharides isolated from total cellular 35SO4-labeled macromolecules of different mammalian cell lines. The first class carries various combinations of sialic acids and 6-O-sulfate esters on typical complex-type chains, while the second carries heparin and heparan-like sequences. In this study, we have characterized a sulfophosphoglycoprotein of 140 kDa from FG-Met-2 pancreatic cancer cells whose oligosaccharides share some properties of both these classes. The molecule was localized to the cell surface by electron microscopy using a monoclonal antibody (S3-53) and by cell surface 125I-labeling. Metabolic labeling of the cells with radioactive glucosamine, methionine, inorganic sulfate, or phosphate all demonstrated a single 140-kDa molecule. Pulse-chase analysis and tunicamycin treatment indicated the glycosylation of a putative primary translation product of 110 kDa via an intermediate (120 kDa) to the mature form (140 kDa). Digestion with peptide:N-glycosidase F (PNGaseF) indicated a minimum of four N-linked glycosylation sites. PNGaseF released more than 90% of the [6-3H]GlcNH2 label and 40-70% of 35SO4 label from the immunoprecipitated 140-kDa molecule. The isolated oligosaccharides were characterized as described in the preceding two papers. The majority of [6-3H]GlcNH2-labeled molecules were susceptible to neuraminidase. More than 50% of the 35SO4 label was associated with only 5-10% of the 3H-labeled chains. Some of the sulfated chains were partly sialylated molecules with four to five negative charges. Treatment with nitrous acid released about 25% of the 35SO4 label as free sulfate, together with 6% of the [6-3H]GlcNH2 label, indicating the presence of N-sulfated glucosamine residues. Some of these oligosaccharides were degraded by heparinase and heparitinase. Therefore, while they are not as highly charged as typical heparin or heparan chains, they must share structural features that permit recognition by the enzymes. Thus, this 140-kDa glycoprotein contains at least four asparagine-linked chains substituted with a heterogeneous mixture of sulfated sequences. The heterogeneity of these molecules is as extensive as that described for whole-cell sulfated N-linked oligosaccharides in the preceding two papers.     

A cytoskeleton-associated plasma membrane heparan sulfate proteoglycan in Schwann cells

Schwann cells cocultured with sensory neurons in a serum-free medium accumulate a single species of radiolabeled heparan sulfate proteoglycan (HS-PG) during incubation in medium containing 35SO4. This HS-PG was poorly extracted from cultures by solutions containing 1% Triton X-100 in low salt buffer or by solutions containing 1 M KCl, 4 M urea plus dithiothreitol, 1 mM Tris-HCl, 5 mM EDTA, or 100 micrograms/ml of heparin. The HS-PG was efficiently extracted, however, by 1% Triton X-100 in the presence of 1 M KCl or by 1% deoxycholate. These treatments solubilize both cell membranes and the Schwann cell cytoskeleton. In intact cells the HS-PG was digested by trypsin, indicating it was at least partially exposed on the cell surface. When solubilized HS-PG was applied to a column of octyl-sepharose CL-4B, more than 90% was retained by the column, but was quantitatively eluted by a solution containing 1% Triton X-100. In addition, the solubilized HS-PG could be incorporated into artificial phospholipid vesicles. These results indicate the HS-PG is an integral plasma membrane protein. The inability of low ionic strength solutions containing Triton X-100 to solubilize the HS-PG suggested it was bound to an additional structure. To determine whether the HS-PG was associated with the cytoskeleton we isolated cytoskeletons by detergent lysis of cells and centrifugation. The major protein components of isolated cytoskeletons were spectrin (Mr 225,000), vimentin (Mr 58,000), and actin (Mr 45,000). When 35SO4-labeled cells were used to prepare cytoskeletons approximately 80% of the total HS-PG was recovered in the cytoskeleton fraction. These results suggest the HS-PG is an externally exposed integral plasma membrane protein that is anchored to the Schwann cell cytoskeleton.     

Sulfated compounds in the zymogen granules of the guinea pig pancreas

Sulfate incorporation into the guinea pig pancreas was investigated by light (LM) and electron microscope (EM) autoradiography using a system of minilobules incubated in vitro for 60 min in Krebs-Ringer bicarbonate medium (KRB) containing 35SO4(-2). In acinar cells, examined by EM autoradiography, the label was found concentrated over Golgi elements (including condensing vacuoles) and zymogen granules. 35SO4(-2) was also incorporated by the epithelial cells of the entire pancreatic duct system, the incorporation being surprisingly high in the epithelium of the major ducts. In all ductal epithelia, autoradiographic grains appeared over the Golgi complex and the plasmalemma. Since a contribution of duct epithelium to the sulfated compounds found in the discharged secretion could not be ruled out, a purified zymogen granule fraction was used as a source material for the isolation of sulfated compounds of acinar origin. The presence of 35S- radioactivity in the zymogen granules and condensing vacuoles of this fraction was ascertained by autoradiography (of sectioned pellets). From a lysate of this zymogen granule fraction, a soluble sulfated compound of low isoelectric point and high molecular weight was isolated by gel filtration under conditions that allowed its satisfactory separation from the bulk of the secretory proteins.     

Glycosylation as a Criterion for Defining Subpopulations of Fast-Transported Proteins

The role carbohydrate residues may play in the sorting of newly synthesized fast-transported proteins during the initiation of fast axonal transport has been examined by identifying individual fast-transported glycoproteins that contain either or both fucose and galactose. [3H]Fucose or [3H]galactose was incorporated together with [35S]methionine in vitro in bullfrog dorsal root ganglia. Fast-transported proteins that accumulated proximal to a ligature on the spinal nerve were separated via two-dimensional gel electrophoresis, and 92 gel spots were analyzed quantitatively for the presence of 35S and 3H. Of these spots, 56 (61%) contained either or both fucose and galactose. Glycomoieties were generally associated with families of charged spots whose isoelectric points could be altered with neuraminidase treatment. Single spots tended to be unglycosylated and were unaffected by neuraminidase. The prevalence of glycoproteins was considerably greater in the higher-molecular weight range. Of the 55 spots analyzed with molecular weight greater than approximately 35,000 daltons, 89% were glycosylated, whereas only 19% of the 37 spots with lower molecular weight contained sugar moieties. When considered in light of previous studies in which similar subpopulations have been described, the current findings suggest that the presence or absence of glycomoieties may represent another criterion by which proteins are sorted during the initiation of fast axonal transport.     

In vitro sulfation of sublingual salivary gland mucin: structures of 35S-labeled oligosaccharides

The enzyme which catalyzes the transfer of sulfate ester group from 3'-phosphoadenosine-5'-phosphosulfate to salivary mucus glycoprotein was located in the detergent extract of the Golgi-rich membrane fraction of rat sublingual salivary glands. Alkaline borohydride reductive cleavage of the synthesized 35S-labeled glycoprotein led to the liberation of the label into the reduced acidic oligosaccharide fraction. A 90.3% of the total label was found incorporated in two oligosaccharides. These were identified in order of abundance as sulfated penta- and heptasaccharides. The pentasaccharide was characterized as SO3H,6G1cNAc beta 1,3Ga1 beta 1, 4G1cNAc beta 1,3(NeuAc alpha 2,6)Ga1NAc-01, and the heptasaccharide as SO3H,6G1cNAc beta 1,3Ga1 beta 1,4G1cNAc beta 1,3Ga1 beta 1,4 G1cNAc beta 1,3(NeuAc alpha 2,6)Ga1NAc-01.     

Sulfated secreted forms of bovine and porcine parathyroid chromogranin A (secretory protein-I)

Chromogranin A (secretory protein-I) is an acidic sulfated glycoprotein found in secretory granules of most endocrine and neuroendocrine cells. In the parathyroid it is co-stored and secreted with parathormone in response to hypocalcemia. Differences in post-translational modifications have been reported between chromogranin A from the bovine adrenal and porcine parathyroid glands. The former has been reported to be sulfated mainly on oligosaccharide residues and apparently includes a proteoglycan form, whereas the latter was previously reported to be tyrosine sulfated with little of the proteoglycan form present. Here we have directly compared 35SO4-labeled parathyroid chromogranin A from the pig and the cow to determine if these reported differences were tissue or species specific. We find that the chromogranin A secreted by the bovine gland contains a proteoglycan form, whereas that from the porcine gland does not. Moreover, chromogranin A of both species is primarily sulfated on oligosaccharide residues with little if any tyrosine sulfate detected. Differences were detected in the structure of sulfated O-linked oligosaccharides in bovine and porcine parathyroid chromogranin A.     

Two membrane-bound forms of tyrosylprotein sulfotransferase as revealed by phase partitioning in Triton X-114.

Tyrosylprotein sulfotransferase (TPST) is a membrane-associated enzyme of the trans Golgi network that catalyzes the posttranslational sulfation of a variety of secretory and membrane proteins. We have analyzed the membrane association of TPST in Golgi-enriched fractions from bovine adrenal medulla using carbonate treatment (pH 11) and Triton X-114 phase partitioning. TPST was not extracted by carbonate. Triton X-114 phase partitioning revealed that, unexpectedly, TPST from non-carbonate-treated membranes was present in both, a hydrophilic and a hydrophobic form with apparent sedimentation coefficients of approximately 13 and approximately 6, respectively. Extraction of membranes with carbonate converted the hydrophilic form TPST to the hydrophobic form. Addition of the carbonate extract to TPST solubilized from carbonate-treated membranes converted the hydrophobic form of the enzyme to the hydrophilic form. This conversion of TPST was specific in that it was not observed for the bulk of the proteins present in the carbonate-treated membranes. The factor in the carbonate extract responsible for this conversion, referred to as "phase-transfer factor", (i) was precipitable with ammonium sulfate and polyethylene glycol, (ii) was non-dialyzable, (iii) was not extracted from membranes by 0.5 M NaCl, and (iv) appeared to be more abundant than TPST itself. These results show that TPST is an integral membrane protein and suggested that the enzyme may exist in a complex with a peripheral membrane protein. Moreover, a phase-transfer factor was also observed in another system, PC12 cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

Enzymatic sulfation of mucus glycoprotein in rat submandibular salivary gland

1. The enzymic activity which catalyzes transfer of sulfate ester group from 3'-phosphoadenosine-5'-phosphosulfate to mucus glycoprotein was found associated with Golgi-rich membrane fraction of rat submandibular salivary gland. 2. Optimum enzyme activity was obtained with 0.5% Triton X-100, 4 mM MgCl2 and 25 mM NaF at a pH of 6.8 using desulfated submandibular salivary mucus glycoprotein. The apparent Km of the enzyme for mucus glycoprotein was 11.1 mg/ml. 3. Alkaline borohydride reductive cleavage of the synthesized 35S-labeled glycoprotein led to the liberation of the label into reduced oligosaccharides. A 75.4% of the label was found incorporated in four oligosaccharides. These were identified in order of abundance as sulfated penta-, tri-, hepta- and nonsaccharides. 4. Based on the results of chemical and enzymatic analyses of the intact and desulfated compounds the pentasaccharide was characterized as SO3H----GlcNAc beta----Gal beta----GlcNAc(NeuAc alpha----)GalNAc-ol and the trisaccharide as SO3H----GlcNAc beta----Gal beta----GalNAc-ol.