Echinococcus granulosus: antigen characterization by chemical treatment and enzymatic deglycosylation.

Parasite antigenic fractions obtained by biochemical purification of sheep hydatid fluid were subjected to enzymatic digestion. The relative mobilities of the 5 and B antigens, before and after treatment, were analyzed by polyacrylamide gel electrophoresis (SDS-PAGE) and Western blot. Antigenic fractions transferred to nitrocellulose were also treated with sodium metaperiodate and concanavalin A. The results indicate that antigen 5 contains a substantial amount of carbohydrates covalently linked to a polypeptide backbone, which strongly bind to concanavalin A and is removed by N-glycosidase F (PNGase F). Antigen 5 possesses complex N-linked oligosaccharides (PNGase F sensitive), without terminal N-acetyl-D-glucosamine residues (N-acetyl-D-glucosaminidase nonsensitive) and has no high-mannose oligosaccharides (endo-beta-N-acetylglucosaminidase H nonsensitive). In contrast, the antigen B of low molecular weight is not susceptible to either enzymatic digestions (PNGase F, Endo H, and N-acetyl-D-glucosaminidase) or sodium metaperiodate oxidation and it does not bind to concanavalin A. Polyclonal antibodies prepared against the two antigens reacted with the deglycosylated antigen 5 in Western blot. The dominant epitopes are, therefore, polypeptides, although the presence of carbohydrate epitopes in the native glycoproteins cannot be excluded.     

The role of carbohydrate in thyrotropin action assessed by a novel approach using enzymatic deglycosylation

Deglycosylation of thyrotropin (TSH) and gonadotropins by chemical methods virtually abolishes their biological activity without impairing receptor binding activity. Recent reports have suggested that enzymatic deglycosylation, using endoglycosidases caused a much smaller decrease, if any, in the potency of the glycoprotein hormones without altering the Vmax. However, in these studies complete removal of the carbohydrate chains from the hormones was not unequivocally documented. We have prepared completely deglycosylated bovine TSH by endoglycosidase F digestion of its subunits, which were more readily deglycosylated than the intact hormone. The deglycosylated subunits were separated from any incompletely digested subunits by concanavalin A affinity chromatography. Carbohydrate compositional analysis, using a highly sensitive pulsed amperometric detection method coupled to ion-exchange high performance liquid chromatography, was performed to ascertain the complete removal of the glycan moieties from the subunits. The deglycosylated subunits thus prepared were recombined to obtain deglycosylated TSH dimer. Receptor binding activity of bTSH was minimally affected by the carbohydrate removal. In an in vitro bioassay using stimulation of cyclic AMP production in FRTL-5 cells, deglycosylated bTSH showed reduced activity with a potency 5-10-fold lower than that of control, although the Vmax remained unaltered. In contrast, the deglycosylated bTSH showed a reduction in Vmax, when assayed for its adenylyl cyclase stimulating activity in bovine thyroid membranes. Previous reports using chemical methods have apparently overestimated the effects of deglycosylation, probably because of altered protein conformation, while those using endoglycosidases have apparently underestimated these effects, probably because of incomplete deglycosylation.     

Fungal sensitivity to and enzymatic deglycosylation of ginsenosides

A ginseng pathogen, Cylindrocarpon destructans, and five nonpathogens were tested for their sensitivity to a total ginsenoside fraction (T-GF), a protopanaxadiol-type ginsenoside fraction (PPD-GF) and a protopanaxatriol-type ginsenoside fraction (PPT-GF) from the roots of Panax ginseng C.A. Meyer. The results showed that T-GF inhibited growth of the five ginseng nonpathogens, while it promoted growth of the ginseng pathogen C. destructans. PPT-GF and PPD-GF both inhibited the growth of the five ginseng nonpathogens, although the activity of PPT-GF was higher than that of PPD-GF. PPT-GF and PPD-GF exhibited different activities on C. destructans: PPT-GF inhibited its growth, whereas PPD-GF significantly enhanced its growth. The subsequent analysis of enzymatic degradation of ginsenosides by the test fungi showed that C. destructans can consecutively hydrolyze the terminal monosaccharide units from the sugar chains attached at C3 and C20 in PPD-type ginsenosides by extracellular glycosidase activity to yield four major products, gypenoside XVII (G-XVII), compound O, compound Mb and the ginsenoside F₂. By contrast, the ginseng nonpathogens Aspergillus nidulans and Cladosporium fulvum have no extracellular glycosidase activity toward sugar chains attached to C3 in PPD-type ginsenosides. These results indicated that ginsenosides might act as host chemical defenses, while the ginseng root pathogenic fungi might counter their toxicity by converting PPD-type ginsenosides into growth or host recognition factors. The ability of ginseng root pathogens to deglycosylate PPD-type ginsenosides may be a pathogenicity factor.     

Identification and enzymatic deglycosylation of the myometrial oxytocin receptor using a radioiodinated photoreactive antagonist.

To identify and characterize oxytocin receptors, a 125I-labeled photoreactive oxytocin antagonist was synthesized. The specific oxytocin antagonist [1-(beta-mercapto-beta,beta- cyclopentamethylenepropionic acid), 2-O-methyltyrosine,4-threonine,8- ornithine,9-tyrosylamide]oxytocin ([Mca,Tyr(O-Me)2,Thr4,Orn8,Tyr9-NH2]oxytocin) described by Elands et al. (Elands, J., Barberis, C., Jard, S., Tribollet, E., Dreifuss, J.-J., Bankowski, K., Manning, M., and Sawyer, W. H. (1987) Eur. J. Pharmacol. 147, 192-207) bound to the guinea pig uterine oxytocin receptor with high affinity (apparent Kd = 0.74 nM). The introduction of a 4-azidophenylamidino group at Orn8 resulted in the photoreactive ligand [Mca1,Tyr(O-Me)2,Thr4,Orn(4-azidophenylamidino)8,Tyr9- NH2]oxytocin, which retained the high binding affinity (Kd = 0.69 nM) of the parent compound. The photoreactive antagonist monoiodinated at Tyr9 had approximately double (Kd = 0.39 nM) the affinity of the photoreactive antagonist and several times that of oxytocin (Kd = 2.6 nM) for the guinea pig uterine oxytocin receptor. In photo-affinity labeling experiments using myometrial membranes obtained from guinea pigs during late pregnancy, the 125I-labeled photoreactive antagonist specifically labeled a protein with an apparent molecular mass of between 68 and 80 kDa: the labeling of this protein was completely suppressed by a 100-fold molar excess of oxytocin and oxytocin receptor-specific agonists, but not by vasopressin analogues specific for V1 or V2 receptors or by other peptide hormones. The ability of oxytocin to suppress labeling was decreased in the presence of guanosine 5'-O-(thiotriphosphate) or in the absence of Mn2+. Digestion of the photolabeled oxytocin receptor with endoglycosidase F gave rise to a protein with an apparent molecular mass of 38 +/- 2 kDa. The endoglycosidase F effect and the lack of endoglycosidase H action show that the myometrial oxytocin receptor is highly glycosylated with asparagine-linked complex oligosaccharide chains. Our results suggest that the radioiodinated photoreactive oxytocin antagonist could be a helpful tool in the isolation and further characterization of the oxytocin receptor.     

The NSILA-s receptor in liver plasma membranes. Characterization and comparison with the insulin receptor.

NSILA-s (nonsuppressible insulin-like activity, soluble in acid ethanol) is a serum peptide that has insulin-like and growth-promoting activities. We have demonstrated previously that liver plasma membranes possess separate receptors for NSILA-s and insulin and have characterized the insulin receptor in detail. In the present study we have characterized the properties and specificity of the NSILA-s receptor and compared them to those of the insulin receptor in the same tissue. Both 125I-NSILA-s and 125I-insulin bind rapidly and reversibly to their receptors in liver membranes; maximal NSILA-s binding occurs at 20 degrees while maximal insulin binding is seen at 1-4 degrees. The pH optimum for NSILA-s binding is broad (6.0 to 8.0), in contrast to the very sharp pH optimum (7.5 to 8.0) for insulin binding. Both receptors exhibit a high degree of specificity. With the insulin receptor, NSILA-s and insulin analogues compete for binding in proportion to their insulin-like potency: insulin greater than proinsulin greater than NSILA-s. With the NSILA-s receptor, NSILA-s is most potent and the order is reversed: NSILA-s greater than proinsulin greater than insulin. Furthermore, six preparations of NSILA-s which varied 70-fold in biological activity competed for 125I-NSILA-s binding in order of their potencies. NSILA-s which had been inactivated biologically by reduction and aminoethylation and growth hormone were less than 1/100,000 as potent as the most purified NSILA-s preparation. Purified preparations of fibroblast growth factor, epidermal growth factor, nerve growth factor, and somatomedins B and C were less than 1% as effective as NSILA-s in competing for the 125I-NSILA-s suggesting that these factors act through other receptors. In contrast, somatomedin A was 10% as active as NSILA-s and multiplication-stimulating activity was fully as active as NSILA-s in competing for the NSILA-s receptor. Analysis of the data suggests that there are approximately 50 times more insulin receptors than NSILA-s receptors per liver cell, while the apparent affinity of NSILA-s receptors is somewhat higher than that of the insulin receptor.     

Accessibility of the carbohydrate moiety of membrane-bound rhodopsin to enzymatic and chemical modification

Galactose was specifically inserted into the carbohydrate moiety of rhodopsin by incubating retinal disk membranes with UDP-galactose: N-acetylglucosamine galactosyltransferase. The stoichiometry of labeling ranged from 1.2 to 1.8 (average = 1.5) residues of galactose per molecule of rhodopsin, indicating that some or all of the oligosaccharide chains of membrane-bound rhodopsin are readily accessible to enzymatic modification. These modified membranes were treated with galactose oxidase to generate an aldehyde at the C-6 position of the inserted galactose units. The enzymatically-oxidized membranes were then reacted with dansyl hydrazide to yield a fluorescent hydrazone which is sufficiently stable to permit spectroscopic analysis. This procedure for the specific attachment of a spectroscopic probe should be applicable to a wide variety of membrane glycoproteins.     

Mapping of carbohydrate sites on the human insulin receptor

Prior to investigating the role of individual glycosylation sites in insulin receptor function, we are mapping the sites of glycosylation in the receptor. We report here a generally applicable methodology for the isolation and identification of glycosylation sites in cell surface glycoproteins. Human insulin receptors were labeled with [3H]-sugars using a CHO cell line transfected with the human receptor cDNA. Labelled receptors were mixed with receptors purified from human placental membranes and tryptic peptides prepared. Peptides were fractionated by gel filtration chromatography to limit the number of non-glycopeptides present. Peptides were then separated by reverse phase HPLC and glycopeptides identified by scintillation counting. Using this technique we have shown the insulin receptor to be glycosylated at Asn 397 and Asn 881. This increase the known number of occupied glycosylation sites to five.     

Characterization of skeletal muscle insulin receptor

The insulin receptor from rat skeletal muscle was characterized. Treatment of muscle membranes with the photoactive insulin analog, 125I[N-epsilonB29-monoazidobenzoyl]-insulin revealed a single protein band of 135,000 Da, the alpha subunit. Iodination of total membrane protein followed by Triton X-100 solubilization and immunoprecipitation demonstrated the presence of a protein band of 90,000 Da, the beta subunit, together with a protein band of 190,000 Da, which may be the receptor precursor. In partially purified receptor preparations, the beta subunit exhibited dose-dependent, insulin-stimulated phosphorylation with incorporation of phosphate solely into tyrosine residues, which was also observed in the 190,000-Da receptor precursor. Purified plasma membranes contained a large amount of insulin-degrading activity which had to be inactivated prior to performing insulin-binding studies. If degradation of insulin was not prevented, apparent enhanced binding in the presence of unlabeled insulin was observed.     

Characterization of Drosophila insulin receptor substrate

Insulin receptor substrate (IRS) proteins are phosphorylated by multiple tyrosine kinases, including the insulin receptor. Phosphorylated IRS proteins bind to SH2 domain-containing proteins, thereby triggering downstream signaling pathways. The Drosophila insulin receptor (dIR) C-terminal extension contains potential binding sites for signaling molecules, suggesting that dIR might not require an IRS protein to accomplish its signaling functions. However, we obtained a cDNA encoding Drosophila IRS (dIRS), and we demonstrated expression of dIRS in a Drosophila cell line. Like mammalian IRS proteins, the N-terminal portion of dIRS contains a pleckstrin homology domain and a phosphotyrosine binding domain that binds to phosphotyrosine residues in both human and Drosophila insulin receptors. When coexpressed with dIRS in COS-7 cells, a chimeric receptor (the extracellular domain of human IR fused to the cytoplasmic domain of dIR) mediated insulin-stimulated tyrosine phosphorylation of dIRS. Mutating the juxtamembrane NPXY motif markedly reduced the ability of the receptor to phosphorylate dIRS. In contrast, the NPXY motifs in the C-terminal extension of dIR were required for stable association with dIRS. Coimmunoprecipitation experiments demonstrated insulin-dependent binding of dIRS to phosphatidylinositol 3-kinase and SHP2. However, we did not detect interactions with Grb2, SHC, or phospholipase C-gamma. Taken together with published genetic studies, these biochemical data support the hypothesis that dIRS functions directly downstream from the insulin receptor in Drosophila.     

Characterization of an interaction between insulin receptor substrate 1 and the insulin receptor by using the two-hybrid system.

Insulin receptor substrate 1 (IRS-1) is a major substrate of the insulin receptor and has been implicated in insulin signaling. Although IRS-1 is thought to interact with the insulin receptor, the nature of the interaction has not been defined. In this study, we used the two-hybrid assay of protein-protein interaction in the yeast Saccharomyces cerevisiae to study the interaction between human IRS-1 and the insulin receptor. We demonstrate that IRS-1 forms a specific complex with the cytoplasmic domain of the insulin receptor when both are expressed as hybrid proteins in yeast cells. We show that the interaction is strictly dependent upon receptor tyrosine kinase activity, since IRS-1 shows no interaction with a kinase-inactive receptor hybrid containing a mutated ATP-binding site. Furthermore, mutation of receptor tyrosine 960 to phenylalanine eliminates IRS-1 interaction in the two-hybrid assay. These data suggest that the interaction between IRS-1 and the receptor is direct and provide evidence that the juxtamembrane domain of the receptor is involved. Furthermore, we show that a 356-amino-acid region encompassed by amino acids 160 through 516 of IRS-1 is sufficient for interaction with the receptor in the two-hybrid assay. Lastly, in agreement with our findings for yeast cells, we show that the insulin receptor is unable to phosphorylate an IRS-1 protein containing a deletion of amino acids 45 to 516 when expressed in COS cells. The two-hybrid assay should provide a facile means by which to pursue a detailed understanding of this interaction.     

Characterization of chemical substitution of hydroxypropyl cellulose using enzymatic degradation

The distribution of substituents along the polymer backbone will have a strong influence on the properties of modified cellulose. Endoglucanases were used to degrade a series of hydroxypropyl cellulose (HPC) derivatives with a high degree of substitution. The HPCs were characterized with cloud-point analysis prior to degradation. The extent of enzymatic degradation was determined with size-exclusion chromatography with online multi-angle light scattering and refractive index detection and also with high-pH anion exchange chromatography with pulsed amperometric detection. To further characterize the formed products, matrix-assisted laser desorption/ionization time-of-flight mass spectrometry was employed for analysis of short-chained oligosaccharides. The different endoglucanases showed varying degradation capability depending on structure of the active site. The highly substituted HPCs had different susceptibility to degradation by the endoglucanases. The results show a difference in substituent distribution between HPCs, which would explain the differing cloud-point behaviors. Increased number of regions with low substitution could be correlated with lower polymer cloud point. The study shows the usefulness of enzymatic degradation to study the distribution of substituents in soluble biopolymer derivates.     

A chemical method for the deglycosylation of proteins

A simple and rapid chemical method for the deglycosylation of glycoproteins has been developed. The method involves the incubation of protein with trifluoromethanesulfonic acid at 0 degrees C from 0.5 to 2 h followed by the neutralization of the acid with aqueous pyridine at -20 degrees C. The method has been applied effectively to fetuin, ovine submaxillary mucin, ovine lutropin, and human choriogonadotropin. In 1 h almost all of N- and O-linked carbohydrates from ovine lutropin and human choriogonadotropin, with the exception of the linkage N-acetylglucosamine or N-acetylgalactosamine, were removed. Similarly, in 1 h all N-linked carbohydrates, excepting again the linkage sugar, in fetuin were degraded. Longer reaction times up to 2 h completely removed the O-linked carbohydrate chains from fetuin and ovine submaxillary mucin. The deglycosylated hormones thus prepared retained their immunological and biological activities.     

Detection and enzymatic deglycosylation of a glycosylated variant of prolactin in human plasma

Immunoperoxidase electrophoresis was applied to the plasma of a patient showing a high level of prolactin (PRL) secreted by a pituitary adenoma. Two PRL monomers were detected with an anti-hPRL antiserum: a major 22 kDa form and a minor 25 kDa form. Concanavalin A-Sepharose 4B chromatography revealed that the 25 kDa form was a glycosylated variant of PRL. Incubation of this variant with endoglycosidase F led to its transformation into the 22 kDa form.     

Effects of enzymatic deglycosylation on the biological activities of human thrombin and antithrombin

Sequential digestion of human thrombin and antithrombin with neuraminidase, βgalactosidase, β-N-acetylglucosaminidase, and endo-β-N-acetylglucosaminidase D resulted in the successive removal of sialic acid, galactose, N-acetylglucosamine, and mannose and more N-acetylglucosamine residues. The products obtained after each stage of deglycosylation had electrophoretic mobilites that were consistent with the calculated change in mass expected from the cleavage of the sugar moieties. The modified thrombins did not lose fibrinogen-clotting activity, amidolytic activity, nor the ability to form complexes with antithrombin. In addition, asialothrombin and asialoagalactothrombin caused the same extent of platelet release as did control thrombin. The products obtained after removal of sugars from antithrombin retained thrombin-neutralizing activity. In the presence of heparin the inhibition of thrombin as well as factor Xa was enhanced. Thus, the sugar residues of thrombin and antithrombin are not required for the formation of enzyme-inhibitor complexes or for the other activities that were measured.     

Characterization of insulin receptor subunits in brain and other tissues by photoaffinity labeling

Specific insulin receptor proteins of plasma membrane preparations from various tissues of the rat were identified using a photoreactive insulin derivative, N^εB29-mono(azidobenzoyl)insulin. Except for the brain, all tissues examined showed the specific photolabeling of two proteins of M_r～130K and ～90K. In brain tissue, only one protein, M_r～115K, was specifically labeled. Liver and adipocyte membranes of the genetic obese ($\text{ob}\text{ob}$) mice showed decreased labeling of both 130K and 90K proteins when compared to those of lean littermates. Labeling of these proteins in liver plasma membranes was abolished by trypsin, whereas neuraminidase increased their electrophoretic mobility in SDS-polyacrylamide gel. The labeling of these two proteins was inhibited by a human anti-receptor serum which also formed an immunocomplex with both proteins. The labeling of the 115K protein in brain tissue was, however, not affected by the antiserum.     

Lectin binding and enzymatic deglycosylation of the cGMP-gated channel from bovine rod photoreceptors

In order to investigate the lectin-binding properties of the photoreceptor cGMP-gated channel, solubilized and purified channel protein was incubated with immobilized lectins followed by reconstitution of unbound proteins. Of the lectins tested, only concanavalin A (ConA) was able to specifically sediment channel activity. A 240-kDa protein, which copurifies with the 63-kDa channel protein but does not bind ConA, was also found to be sedimented by the ConA-affinity matrix, thereby implicating that it is associated with the channel complex. Treatment of the purified channel protein with the enzyme glycopeptidase F in the presence of the denaturing detergent sodium dodecyl sulfate resulted in a rapid reduction of the apparent molecular mass by 1.90 kDa, and the abolition of ConA-binding. No intermediate molecular weight species were observed, suggesting that the channel protein is N-glycosylated at one site only. Under nondenaturing conditions, the kinetics of deglycosylation were distinctly two-phased: 50-60% deglycosylation was achieved rapidly; however, prolonged incubation was required to arrive at complete deglycosylation. Reconstitution experiments showed that deglycosylation had no significant effect on the kinetics of channel protein activation by cGMP.     

Effects of enzymatic deglycosylation of human goiter thyroglobulin on its immunochemical properties

Thyroglobulin (Tg), isolated from soluble iodoproteins by ammonium sulphate fractionation, was enzymatically deglycosylated in vitro and analyzed by polyacrylamide gel electrophoresis, double immunodiffusion and non-commercial RIA. Carbohydrate and iodine content was chemically determined. By PAAGE deglycosylated Tg (dTg) showed the appearance of a major band in the 12S region and three slower migrating bands corresponding to higher aggregates than 19S Tg. In immunodiffusion by testing native and deglycosylated Tg against anti-native Tg antiserum it was shown the appearance of a spur of native on deglycosylated Tg. By RIA of native and deglycosylated Tg against anti-deglycosylated Tg antiserum it was shown a minor binding capacity of the anti-deglycosylated antibody against native Tg at high dilutions. The results demonstrate that the enzymatic deglycosylation release almost all the carbohydrates of goiter Tg and that the removal of the carbohydrates of Tg produces a loss of antigenic determinants of the molecule.     

Characterization of the functional insulin binding epitopes of the full-length insulin receptor

Mutational analyses of the secreted recombinant insulin receptor extracellular domain have identified a ligand binding site composed of residues located in the L1 domain (amino acids 1-470) and at the C terminus of the alpha subunit (amino acids 705-715). To evaluate the physiological significance of this ligand binding site, we have transiently expressed cDNAs encoding full-length receptors with alanine mutations of the residues forming the functional epitopes of this binding site and determined their insulin binding properties. Insulin bound to wild-type receptors with complex kinetics, which were fitted to a two-component sequential model; the Kd of the high affinity component was 0.03 nM and that of the low affinity component was 0.4 nM. Mutations of Arg14, Phe64, Phe705, Glu706, Tyr708, Asn711, and Val715 inactivated the receptor. Alanine mutation of Asn15 resulted in a 20-fold decrease in affinity, whereas mutations of Asp12, Gln34, Leu36, Leu37, Leu87, Phe89, Tyr91, Lys121, Leu709, and Phe714 all resulted in 4-10-fold decreases. When the effects of the mutations were compared with those of the same mutations of the secreted recombinant receptor, significant differences were observed for Asn15, Leu37, Asp707, Leu709, Tyr708, Asn711, Phe714, and Val715, suggesting that the molecular basis for the interaction of each form of the receptor with insulin differs. We also examined the effects of alanine mutations of Asn15, Gln34, and Phe89 on insulin-induced receptor autophosphorylation. They had no effect on the maximal response to insulin but produced an increase in the EC50 commensurate with their effect on the affinity of the receptor for insulin.     

Characterization of the bombesin receptor on mouse pancreatic acini by chemical cross-linking

Bombesin (BN), gastrin-releasing peptide (GRP) and GRP(18–27) (neuromedin C) were equipotent and 30-fold more potent than neuromedin B (NMB) in inhibiting binding of ¹²⁵I-GRP to and in stimulating amylase release from mouse pancreatic acini. In the present study we used ¹²⁵I-GRP and chemical cross-linking techniques to characterized the mouse pancreatic BN receptor. After binding of ¹²⁵I-GRP to membranes, and incubation with various chemical cross-linking agents, cross-linked radioactivity was analyzed by SDS-PAG electrophoresis and autoradiography. With each of 4 different chemical cross-linking agents, there was a single broad polypeptide band of Mr 80,000. Cross-linking did not occur in the absence of the cross-linking agent. Cross-linking was inhibited only by peptides that interact with the BN receptor such as GRP, NMB, GRP(18–27) or BN. Dose-inhibition curves for the ability of BN or NMB to inhibit binding of ¹²⁵I-GRP to membranes or cross-linking to the 80,000 polypeptide demonstrated for both that BN was 15-fold more potent than NMB. The apparent molecular weight of the cross-linked polypeptide was unchanged by adding dithiothreitol. N-Glycanase treatment reduced the molecular weight of the cross-linked peptide to 40,000. The present results indicate that the BN receptor on mouse pancreatic acinar cell membranes resembles that recently described on various tumor cells in being a single glycoprotein with a molecular weight of 76,000. Because dithiothreitol had no effect, this glycoprotein is not a subunit of a larger disulfide-linked structure.