N-glycosylation is crucial for folding, trafficking, and stability of human tripeptidyl-peptidase I

Tripeptidyl-peptidase I (TPP I) is a lysosomal serine-carboxyl peptidase that sequentially removes tripeptides from polypeptides. Naturally occurring mutations in TPP I are associated with the classic late infantile neuronal ceroid lipofuscinosis. Human TPP I has five potential N-glycosylation sites at Asn residues 210, 222, 286, 313, and 443. To analyze the role of N-glycosylation in the function of the enzyme, we obliterated each N- glycosylation consensus sequence by substituting Gln for Asn, either individually or in combinations, and expressed mutated cDNAs in Chinese hamster ovary and human embryonic kidney 293 cells. Here, we demonstrate that human TPP I in vivo utilizes all five N-glycosylation sites. Elimination of one of these sites, at Asn-286, dramatically affected the folding of the enzyme. However, in contrast to other misfolded proteins that are retained in the endoplasmic reticulum, only a fraction of misfolded TPP I mutant expressed in Chinese hamster ovary cells, but not in human embryonic kidney 293 cells, was arrested in the ER, whereas its major portion was secreted. Secreted proenzyme formed non-native, interchain disulfide bridges and displayed only residual TPP I activity upon acidification. A small portion of TPP I missing Asn-286-linked glycan reached the lysosome and was processed to an active species; however, it showed low thermal and pH stability. N-Glycans at Asn-210, Asn-222, Asn-313, and Asn-443 contributed slightly to the specific activity of the enzyme and its resistance to alkaline pH-induced inactivation. Phospholabeling experiments revealed that N-glycans at Asn-210 and Asn-286 of TPP I preferentially accept a phosphomannose marker. Thus, a dual role of oligosaccharide at Asn-286 in folding and lysosomal targeting could contribute to the unusual, but cell type-dependent, fate of misfolded TPP I conformer and represent the molecular basis of the disease process in subjects with naturally occurring missense mutation at Asn-286.     

N-Glycosylation is requisite for the enzyme activity and Golgi retention of N-acetylglucosaminyltransferase III

UDP-N-acetylglucosamine:ß-D-mannoside ß-1,4N-acetylglucosaminyltransferaseIII (GnT-III, EC 2.4.1.144 [EC] ) is a glycoprotein involved in thebiosynthesis of N-linked oligosaccharides. Rat GnT-III containsthree potential Nglycosylation sites, which have been predictedto be Asn243, Asn261, and Asn399. To study the roles of Nglycosylationin the GnT-III function, rat GnT-III was expressed in COS-1cells under tunicamycin or castanospermine treatment. The tunicamycin-treatedGnT-III, which was not N-glycosylated, had almost no activity.The castanospermine-treated GnT-III was not localized in theGolgi, but glucosylation did not affect its activity. To clarifythe role of individual N-glycosylations, we obtained a seriesof mutant cDNAs in which some or all of the potential glycosylationsites were eliminated by site-directed mutagenesis, and expressedthem in COS-1 cells. All the mutants exhibited lower enzymeactivity than the wild-type, but deglycosylation at individualsites had different effects on the enzyme activity. The deglycosylationat Asn243 or Asn261 was more effective on the activity thanthat at Asn399. The enzyme activity decreased as the numberof glycosylation sites decreased. The null glycosylation mutanthad no activity, corresponding to the case of tunicainycin-treatedwild-type GnT-III. Kinetic analysis revealed that the deglycosylationat Asn243 or Asn.261 resulted in slightly lower affinity forthe donor substrate, but the other mutation did not significantlychange the K_m value for either the donor or acceptor. None ofthe mutant GnT-IIIs showed perinuclear localization or Golgiretention, that was observed for the wild-type protein. Thisis the first demonstration that the glycosyltransferase localizedin the Golgi apparatus requires N-glycosylation for its activityand retention. N-acetylglucosaminyltransferase III N-glycosylation Golgi apparatus glycoprotein protein folding     

Site occupancy and glycan compositional analysis of two soluble recombinant forms of the attachment glycoprotein of Hendra virus

Hendra virus (HeV) continues to cause morbidity and mortality in both humans and horses with a number of sporadic outbreaks. HeV has two structural membrane glycoproteins that mediate the infection of host cells: the attachment (G) and the fusion (F) glycoproteins that are essential for receptor binding and virion-host cell membrane fusion, respectively. N-linked glycosylation of viral envelope proteins are critical post-translation modifications that have been implicated in roles of structural integrity, virus replication and evasion of the host immune response. Deciphering the glycan composition and structure on these glycoproteins may assist in the development of glycan-targeted therapeutic intervention strategies. We examined the site occupancy and glycan composition of recombinant soluble G (sG) glycoproteins expressed in two different mammalian cell systems, transient human embryonic kidney 293 (HEK293) cells and vaccinia virus (VV)-HeLa cells, using a suite of biochemical and biophysical tools: electrophoresis, lectin binding and tandem mass spectrometry. The N-linked glycans of both VV and HEK293-derived sG glycoproteins carried predominantly mono- and disialylated complex-type N-glycans and a smaller population of high mannose-type glycans. All seven consensus sequences for N-linked glycosylation were definitively found to be occupied in the VV-derived protein, whereas only four sites were found and characterized in the HEK293-derived protein. We also report, for the first time, the existence of O-linked glycosylation sites in both proteins. The striking characteristic of both proteins was glycan heterogeneity in both N- and O-linked sites. The structural features of G protein glycosylation were also determined by X-ray crystallography and interactions with the ephrin-B2 receptor are discussed.     

Role of N-linked glycans of HCV glycoprotein E1 in folding of structural proteins and formation of viral particles

Envelope proteins E1 and E2 of the hepatitis C virus (HCV) play a major role in the life cycle of a virus. These proteins are the main components of the virion and are involved in virus assembly. Envelope proteins are modified by N-linked glycosylation, which is supposed to play a role in their stability, in the assembly of the functional glycoprotein heterodimer, in protein folding, and in viral entry. The effects of N-linked glycosylation of HCV protein E1 on the assembly of structural proteins were studied using site-directed mutagenesis in a model system of Sf9 insect cells producing three viral structural proteins with the formation of virus-like particles due to the baculovirus expression system. The removal of individual N-glycosylation sites in HCV protein E1 did not affect the efficiency of its expression in insect Sf9 cells. The electrophoretic mobility of E1 increased with a decreasing number of N-glycosylation sites. The destruction of E1 glycosylation sites N1 or N5 influenced the assembly of the noncovalent E1E2 glycoprotein heterodimer, which is the prototype of the natural complex within the HCV virion. It was also shown that the lack of glycans at E1 sites N1 and N5 significantly reduced the efficiency of E1 expression in mammalian HEK293 T cells.     

Analysis of individual azurocidin N-glycosylation sites in regard to its secretion by insect cells, susceptibility to proteolysis and antibacterial activity

Azurocidin is an inactive serine protease homolog with primary sequence similarity to neutrophil elastase, cathepsin G, and proteinase 3. The aim of this study was to investigate possible consequences of differential glycosylation of azurocidin in regard to its secretion, protein stability as measured by susceptibility to proteolysis, and antibacterial activity. Site-directed mutagenesis was employed to generate mutant azurocidin variants lacking individual N-glycosylation sites. Our results show that N-linked glycans may play a role in proper azurocidin folding and subsequent secretion by insect cells. We also demonstrate that N-linked glycosylation contributes to azurocidin stability by protecting it from proteolysis. The lack of N-glycosylation at individual sites does not significantly influence the azurocidin antibacterial activity.     

Secretion of glycosylated alpha-lactalbumin in yeast Pichia pastoris

The secretion of N-linked glycosylated alpha-lactalbumin was much higher in the expression system of yeast Pichia pastoris carrying goat alpha-lactalbumin cDNA than in mammalian milk. This is possibly because of the presence of N-linked glycosylation signal sequences, Asn(45)-Asp(46)-Ser(47) and Asn(74)-Ile(75)-Ser(76), in wild-type alpha-lactalbumin. Attempts to elucidate the mechanism of the higher secretion of glycosylated alpha-lactalbumin in P. pastoris were made. Mutant N45D that deleted the N-linked glycosylation signal sequence at position 45 predominantly secreted nonglycosylated protein. On the other hand, mutant D46N with another N-glycosylation signal site at position 46 only secreted N-linked glycosylated alpha-lactalbumin, i.e. not the nonglycosylated protein. The total secreted amount of mutant N45D was greatly enhanced, while the secreted amounts of the wild-type and mutant D46N were very low, suggesting that the increase in the number of glycosylation sites greatly reduced the secretion of alpha-lactalbumin. It seems likely that the glycosylated alpha-lactalbumin may be degraded by the quality control system.     

Site-directed removal of N-glycosylation sites in human gastric lipase.

Human gastric lipase (HGL) is a highly glycosylated protein, as glycan chains account for about 15% of the molecular mass of the native HGL. Four potential N-glycosylation consensus sites (Asn15, 80, 252 and 308) can be identified from the HGL amino acid sequence. We studied the functional role of the individual N-linked oligosaccharide chains by removing one by one all the N-glycosylation sites, via Ala residue replacement by site-directed mutagenesis of Ser and Thr residues from the consensus sequences Asn-X-Ser/Thr. Mutagenized cDNA constructs were heterologously expressed in the baculovirus/insect cell system. Removal of oligosaccharides either at Asn15, 80 or 252 was found to have no significant influence on the enzymatic activity measured in vitro. However, the absence of glycosylation at Asn308, as well as a total deglycosylation, reduced the specific enzymatic activity of recombinant HGL (r-HGL), measured on short- and long-chain triglycerides, to about 50% of normal values. Furthermore, biosynthesis and secretion of r-HGL markedly dropped when all four potential glycosylation sites were mutated. The kinetics of the interfacial adsorption of r-HGL and the completely deglycosylated r-HGL (four-site mutant) were found to be identical when recording the changes with time of the surface pressure either at the air-water interface or in the presence of an egg phosphatidylcholine (PtdCho) monomolecular film spread at various initial surface pressures. This indicates that both recombinant HGLs are identical, as far as recognition of phospholipid film and adsorption on PtdCho are concerned. The N-glycosylation of HGL may contribute to the enzyme stability in the stomach, as under acidic conditions the degradation by pepsin of the unglycosylated r-HGL is increased.     

N-Glycans mutations rule oligomeric assembly and functional expression of P2X3 receptor for extracellular ATP

N-Glycosylation affects the function of ion channels at the level of multisubunit assembly, protein trafficking, ligand binding and channel opening. Like the majority of membrane proteins, ionotropic P2X receptors for extracellular ATP are glycosylated in their extracellular moiety. Here, we used site-directed mutagenesis to the four predicted N-glycosylation sites of P2X(3) receptor (Asn(139), Asn(170), Asn(194) and Asn(290)) and performed comparative analysis of the role of N-glycans on protein stability, plasma membrane delivery, trimer formation and inward currents. We have found that in transiently transfected HEK293 cells, Asn(170) is apparently the most important site for receptor stability, since its mutation causes a primary loss in protein content and indirect failure in membrane expression, oligomeric association and inward current responses. Even stronger effects are obtained when mutating Thr(172) in the same glycosylation consensus. Asn(194) and Asn(290) are the most dispensable, since even their simultaneous mutation does not affect any tested receptor feature. All double mutants containing Asn(170) mutation or the Asn(139)/Asn(290) double mutant are instead almost unable to assemble into a functional trimeric structure. The main emerging finding is that the inability to assemble into trimers might account for the impaired function in P2X(3) mutants where residue Asn(170) is replaced. These results improve our knowledge about the role of N-glycosylation in proper folding and oligomeric association of P2X(3) receptor.     

The G82S polymorphism promotes glycosylation of the receptor for advanced glycation end products (RAGE) at asparagine 81: comparison of wild-type rage with the G82S polymorphic variant

Interaction between the receptor for advanced glycation end products (RAGE) and its ligands amplifies the proinflammatory response. N-Linked glycosylation of RAGE plays an important role in the regulation of ligand binding. Two potential sites for N-linked glycosylation, at Asn(25) and Asn(81), are implicated, one of which is potentially influenced by a naturally occurring polymorphism that substitutes Gly(82) with Ser. This G82S polymorphic RAGE variant displays increased ligand binding and downstream signaling. We hypothesized that the G82S polymorphism affects RAGE glycosylation and thereby affects ligand binding. WT or various mutant forms of RAGE protein, including N25Q, N81Q, N25Q/G82S, and N25Q/N81Q, were produced by transfecting HEK293 cells. The glycosylation patterns of expressed proteins were compared. Enzymatic deglycosylation showed that WT RAGE and the G82S polymorphic variant are glycosylated to the same extent. Our data also revealed N-linked glycosylation of N25Q and N81Q mutants, suggesting that both Asn(25) and Asn(81) can be utilized for N-linked glycosylation. Using mass spectrometry analysis, we found that Asn(81) may or may not be glycosylated in WT RAGE, whereas in G82S RAGE, Asn(81) is always glycosylated. Furthermore, RAGE binding to S100B ligand is affected by Asn(81) glycosylation, with consequences for NF-κB activation. Therefore, the G82S polymorphism promotes N-linked glycosylation of Asn(81), which has implications for the structure of the ligand binding region of RAGE and might explain the enhanced function associated with the G82S polymorphic RAGE variant.     

TGF-β sensitivity is determined by N-linked glycosylation of the type II TGF-β receptor

N-linked glycosylation is a critical determinant of protein structure and function, regulating processes such as protein folding, stability and localization, ligand-receptor binding and intracellular signalling. TβRII [type II TGF-β (transforming growth factor β) receptor] plays a crucial role in the TGF-β signalling pathway. Although N-linked glycosylation of TβRII was first demonstrated over a decade ago, it was unclear how this modification influenced TβRII biology. In the present study, we show that inhibiting the N-linked glycosylation process successfully hinders binding of TGF-β1 to TβRII and subsequently renders cells resistant to TGF-β signalling. The lung cancer cell line A549, the gastric carcinoma cell line MKN1 and the immortal cell line HEK (human embryonic kidney)-293 exhibit reduced TGF-β signalling when either treated with two inhibitors, including tunicamycin (a potent N-linked glycosylation inhibitor) and kifunensine [an inhibitor of ER (endoplasmic reticulum) and Golgi mannosidase I family members], or introduced with a non-glycosylated mutant version of TβRII. We demonstrate that defective N-linked glycosylation prevents TβRII proteins from being transported to the cell surface. Moreover, we clearly show that not only the complex type, but also a high-mannose type, of TβRII can be localized on the cell surface. Collectively, these findings demonstrate that N-linked glycosylation is essentially required for the successful cell surface transportation of TβRII, suggesting a novel mechanism by which the TGF-β sensitivity can be regulated by N-linked glycosylation levels of TβRII.     

The assembly of proline-rich membrane anchor (PRiMA)-linked acetylcholinesterase enzyme: glycosylation is required for enzymatic activity but not for oligomerization

Acetylcholinesterase (AChE) anchors onto cell membranes by a transmembrane protein PRiMA (proline-rich membrane anchor) as a tetrameric form in vertebrate brain. The assembly of AChE tetramer with PRiMA requires the C-terminal "t-peptide" in AChE catalytic subunit (AChE(T)). Although mature AChE is well known N-glycosylated, the role of glycosylation in forming the physiologically active PRiMA-linked AChE tetramer has not been studied. Here, several lines of evidence indicate that the N-linked glycosylation of AChE(T) plays a major role for acquisition of AChE full enzymatic activity but does not affect its oligomerization. The expression of the AChE(T) mutant, in which all N-glycosylation sites were deleted, together with PRiMA in HEK293T cells produced a glycan-depleted PRiMA-linked AChE tetramer but with a much higher K(m) value as compared with the wild type. This glycan-depleted enzyme was assembled in endoplasmic reticulum but was not transported to Golgi apparatus or plasma membrane.     

Controlling N-linked glycan site occupancy

N-linked glycosylation, a common co-translational modification in eukaryotic cells, involves the transfer of a lipid-linked oligosaccharide onto asparagine residues in a tripeptide sequon on a nascent protein in the lumen of the endoplasmic reticulum. The attachment of an oligosaccharide unit to the polypeptide at the site of occupancy can enhance solubility, improve folding, facilitate secretion, modulate antigenicity, and increase in vivo half-life of the glycoprotein. A number of proteins exhibit variable site occupancy. The efficiency of protein N-glycosylation is dependent on the kinetics of the individual steps in the biosynthesis of the dolichol-linked oligosaccharide and the transfer of the oligosaccharide from the lipid donor substrate to the nascent polypeptide. In this review, we will discuss the role of N-linked glycan site occupancy and give an overview of the possible limitations associated with variable site occupancy. The characterization of the dolichol pyrophosphate biosynthetic pathway and the recent identification of potential rate limiting enzymes in yeast and mammalian cells has made it possible to investigate their role in site occupancy. Genetic and biochemical characterization of oligosaccharide transferase (OST) complex in yeast and mammalian cells have demonstrated the importance of specific OST subunits in protein N-glycosylation. In addition, insights into the location and residues in and around the acceptor tripeptide sequon suggest an influence on N-glycan site occupancy. Insights from these characterizations are being used to elucidate methodologies to control N-glycosylation site heterogeneity.     

Glycosylation is crucial for a proper catalytic site organization in human glucocerebrosidase

Gaucher disease, an autosomal recessive disorder, is caused by a deficiency of glucocerebrosidase (GCase) enzyme, a peripheral membrane-associated glycoprotein that hydrolyses glucosylceramide in lysosomes. Glycosylation is essential for the development of a catalytically active enzyme, specifically in the first site, located at Asn19. However, both the molecular basis of the relevance of N-glycosylation over GCase activity and the effects of glycosylation over its structure and dynamics are still not fully understood. Thus, the present work evaluated GCase enzyme in increasing glycosylation content using triplicate unbiased molecular dynamics simulations. Accordingly, the N-linked glycan chains caused local conformational stabilization effects over the protein, as well as in regions flanking the enzyme catalytic dyad. In the case of the Asn19-linked glycan, it also occurred around region 438–444, where one of the most prevalent GCase mutations is found. Markedly, an increasing catalytic dyad organization was related to increasing glycosylation contents, offering the first atomic-level explanation for the experimental observation that GCase activity is controlled by glycosylation, especially at Asn19.     

Mutational analysis of the role of N-glycosylation in alpha-factor receptor function

The alpha-factor mating pheromone receptor (encoded by STE2) activates a G protein signaling pathway that stimulates the conjugation of Saccharomyces cerevisiae yeast cells. The alpha-factor receptor is known to undergo several forms of post-translational modification, including phosphorylation, mono-ubiquitination, and N-linked glycosylation. Since phosphorylation and mono-ubiquitination have been shown previously to play key roles in regulating the signaling activity and membrane trafficking of the alpha-factor receptors, the role of N-linked glycosylation was investigated in this study. The Asn residues in the five consensus sites for N-linked glycosylation present in the extracellular regions of the receptor protein were mutated to prevent carbohydrate attachment at these sites. Mutation of two sites near the receptor N-terminus (N25Q and N32Q) diminished the degree of receptor glycosylation, and the corresponding double mutant was not detectably N-glycosylated. The nonglycosylated receptors displayed normal function and subcellular localization, indicating that glycosylation is not important for wild-type receptor activity. However, mutation of the glycosylation sites resulted in improved plasma membrane localization for the Ste2-3 mutant receptors that are normally retained intracellularly at elevated temperatures. These results suggest that N-glycosylation may be involved in the sorting process for misfolded Ste2 proteins, and may similarly affect certain mutant receptors whose altered trafficking is implicated in human diseases.     

Glycosylation of the N-terminal potential N- glycosylation sites in the human α1,3- fucosyltransferase V and -VI (hFucTV and -VI)

Human 1,3-fucosyltransferase V and -VI (hFucTV and -VI) each contain four potential N-glycosylation sites (hFucTV: Asn60, Asn105, Asn167 and Asn198 and hFucTVI: Asn46, Asn91, Asn153 and Asn184). Glycosylation of the two N-terminal potential N-glycosylation sites (hFucTV: Asn60, Asn105 and hFucTVI: Asn46 and Asn91) have never been studied in detail. In the present study, we have analysed the glycosylation of these potential N-glycosylation sites. Initially, we compared the molecular mass of hFucTV and -VI expressed in COS-7 cells treated with tunicamycin with the mass of the proteins in untreated cells. The difference in molecular mass between the proteins in treated and untreated cells corresponded to the presence of at least three N-linked glycans. We then made a series of mutants, in which the asparagine residues in the N-terminal potential N-glycosylation sites were replaced by glutamine. Western blotting analyses demonstrated that both sites in hFucTV were glycosylated, whereas in hFucTVI only one of the sites (Asn91) was glycosylated. All the single mutants and the hFucTVI N46Q/N91Q double mutant exhibited enzyme activities that did not differ considerably from the wt activities. However, the enzyme activity of the hFucTV N60Q/N105Q double mutant was reduced to approximately 40% of the wt activity. In addition, castanospermine treatment diminished the enzyme activity and hence trimming of the N-linked glycans are required for expression of full enzyme activity of both hFucTV and -VI. The present study demonstrates that both of the N-terminal potential N-glycosylation sites in hFucTV and one of the sites in hFucTVI are glycosylated. Individually, their glycosylation does not contribute considerably to expression of enzyme activity. However, elimination of both sites in hFucTV reduces the enzyme activity.     

Secretion of N-glycosylated human recombinant interleukin-1 alpha in Saccharomyces cerevisiae

We have expressed fragments of the cDNA coding for mature human interleukin-1 alpha (hIL-1 alpha) in Saccharomyces cerevisiae. Mature hIL-1 alpha contains one potential N-linked glycosylation site that is not recognized in mammalian cells. Translational fusions to either one of three yeast signal sequences resulted in secretion of bioactive, N-glycosylated hIL-1 alpha. The extent of glycosylation was significantly reduced using the alpha-factor signal sequence, which itself contains three N-linked glycosylation sites known to be core glycosylated. N-glycosylation has no effect on biological specific activity.     

Functional analysis of the C-terminal region of recombinant human thrombopoietin. C-terminal region of thrombopoietin is a "shuttle" peptide to help secretion

Thrombopoietin (TPO) is a cytokine that primarily stimulates megakaryocytopoiesis and thrombopoiesis. TPO has a unique C-terminal tail peptide of about 160 amino acids that consists mostly of hydrophilic residues and contains six N-linked sugar chains. In order to investigate the biological function of the C-terminal domain, two series of mutations were performed. One is systematic truncation from the C terminus. Another is elimination of N-glycosylation sites in the C-terminal domain by Asn to Gln mutations. After the mutant proteins were expressed by mammalian cells, it was found that the elimination of the N-linked sugar sites did not affect the biological activity, whereas truncation of the C-terminal domain resulted in elevation of in vitro activity up to 4-fold. The C-terminal peptide itself was found to inhibit the in vitro activity. Moreover, both the C-terminal truncation and the elimination of the N-glycosylation sites decreased the secretion level progressively down to (1)/(10) that of wild type, and the amount of the mutant left in the cell increased. The N-glycosylation in the C-terminal region was found to be important for secretion of TPO. Among six N-glycosylation sites in the C-terminal region, two locations, Asn-213 and Asn-234, were found to be critical for secretion, and two other locations, Asn-319 and Asn-327, did not affect the secretion.     

Secretion of heparanase protein is regulated by glycosylation in human tumor cell lines

The endo-beta-d-glucuronidase, heparanase, is capable of specifically degrading heparan sulfate, and this activity is associated with the metastatic potential of tumor cells. The predicted amino acid sequence of heparanase includes six putative N-glycosylation sites; however, the precise biochemical role of glycosylated heparanase remains unknown. In this study, we examined the link between glycosylation and the function of heparanase in human tumor cell lines. Heparanase protein was glycosylated at six Asn residues in human tumor cell lines. Treatment with a glycosylation inhibitor demonstrated that glycosylation was not required for the activity of heparanase. However, glycosylation affected the kinetics of endoplasmic reticulum-to-Golgi transport and of secretion of the enzyme.     

The N-linked oligosaccharides at the amino terminus of human apoB are important for the assembly and secretion of VLDL

We determined the role of N-linked glycosylation of apolipoprotein B (apoB) in the assembly and secretion of lipoproteins using transfected rat hepatoma McA-RH7777 cells expressing human apoB-17, apoB-37, and apoB-50, three apoB variants with different ability to recruit neutral lipids. Substituting Asn residue with Gln at the single glycosylation site within apoB-17 (N(158)) decreased its secretion efficiency to a level equivalent to that of wild-type apoB-17 treated with tunicamycin, but had little effect on its synthesis or intracellular distribution. When selective N-to-Q substitution was introduced at one or more of the five N-linked glycosylation sites within apoB-37 (N(158), N(956), N(1341), N(1350), and N(1496)), secretion efficiency of apoB-37 from transiently transfected cells was variably affected. When all five N-linked glycosylation sites were mutated within apoB-37, the secretion efficiency and association with lipoproteins were decreased by >50% as compared with wild-type apoB-37. Similarly, mutant apoB-50 with all of its N-linked glycosylation sites mutagenized showed decreased secretion efficiency and decreased lipoprotein association in both d < 1.02 and d > 1.02 g/ml fractions. The inability of mutant apoB-37 and apoB-50 to associate with very low-density lipoproteins was attributable to impaired assembly and was not due to the limitation of lipid availability. The decreased secretion of mutant apoB-17 and apoB-37 was not accompanied by accumulation within the cells, suggesting that the proportion of mutant apoB not secreted was rapidly degraded. However unlike apoB-17 or apoB-37, accumulation of mutant apoB-50 was observed within the endoplasmic reticulum and Golgi compartments. These data imply that the N-glycans at the amino terminus of apoB play an important role in the assembly and secretion of lipoproteins containing the carboxyl terminally truncated apoB.     

The role of a single N-linked glycosylation site for a functional epitope of herpes simplex virus type 1 envelope glycoprotein gC

A monoclonal antibody, B1C1, binding to an epitope of antigenic site II of the herpes simplex virus type 1 (HSV-1) glycoprotein gC-1, is a potent inhibitor of two important biological functions of gC-1: its binding to cell surface heparan sulfate and its binding to the receptor for complement factor C3b. Here, we have analyzed a B1C1-resistant HSV- 1 variant (HSV-12762/B1C1B4.2), obtained after passage of wild type HSV- 1 (HSV-12762) in the presence of high concentrations of B1C1. The transport of newly synthesized mutant gC-1 to the cell surface was comparable to that of wild type glycoprotein, but no binding of surface- associated mutant gC-1 to B1C1 was detected. However, mutant and wild type gC-1 bound equally well to other site II Mabs. Attachment of wild type but not mutant virus was inhibited by B1C1. Sequencing of the mutant gC-1 gene revealed only one nucleotide change, resulting in replacement of Thr150 by an Ile, in turn destroying an N-glycosylation site at Asn148. Loss of one complex type N-linked glycan was confirmed by endoglycosidase digestion and subsequent SDS-polyacrylamide gel electrophoresis. Circular dichroism analysis of purified gC-1 from cells infected with mutant or wild type virus did not reveal any difference in secondary structure between mutant and wild type gC-1. It was not possible to obtain a B1C1-resistant phenotype by nucleotide- directed mutagenesis of gC-1 where Asn148 was changed to a glutamine. These data demonstrated that the threonine of the glycosylation site and not the N-linked glycan in itself was essential for B1C1 binding