Removal of N-linked glycosylation sites in the V1 region of simian immunodeficiency virus gp120 results in redirection of B-cell responses to V3

One mechanism of immune evasion utilized by human immunodeficiency virus (HIV) and simian immunodeficiency virus (SIV) envelope glycoproteins is the presence of a dense carbohydrate shield. Accumulating evidence from in vitro and in vivo experiments suggests that alterations in N-linked glycosylation of SIV gp120 can enhance host humoral immune responses that may be involved in immune control. The present study was designed to determine the ability of glycosylation mutant viruses to redirect antibody responses to shielded envelope epitopes. The influence of glycosylation on the maturation and specificity of antibody responses elicited by glycosylation mutant viruses containing mutations of specific N-linked sites in and near the V1 and V2 regions of SIVmac239 gp120 was determined. Results from these studies demonstrated a remarkably similar maturation of antibody responses to native, fully glycosylated envelope proteins. However, analyses of antibodies to defined envelope domains revealed that mutation of glycosylation sites in V1 resulted in increased antibody recognition to epitopes in V1. In addition, we demonstrated for the first time that mutation of glycosylation sites in V1 resulted in a redirection of antibody responses to the V3 loop. Taken together, these results demonstrate that N-linked glycosylation is a determinant of SIV envelope B-cell immunogenicity in addition to in vitro antigenicity. In addition, our results demonstrate that the absence of N-linked carbohydrates at specific sites can influence the exposure of epitopes quite distant in the linear sequence.     

Glycosylation affects agonist binding and signal transduction of the rat somatostatin receptor subtype 3.

The somatostatin receptor subtypes, sst1-sst5, bind their natural ligands, somatostatin-14, somatostatin-28 and cortistatin-17, with high affinity but do not much discriminate between them. Detailed understanding of the interactions between these receptors and their peptide ligands may facilitate the development of selective compounds which are needed to identify the biological functions of individual receptor subtypes. The influence of the amino-terminal domain and of the two putative N-linked glycosylation sites located in this region of rat sst3 was analysed. Biochemical studies in transfected cell lines suggested that the amino-terminus of sst3 is glycosylated at both sites. Mutation of the N-linked glycosylation site, Asn18Thr, had only a small effect on binding properties and inhibition of adenylyl cyclase. The double mutant Asn18Thr/Asn31Thr lacking both glycosylation sites showed a significant reduction in high affinity binding and inhibition of adenylyl cyclase while peptide selectivity was not affected. Truncation of the amino-terminal region by 32 amino acid residues including the two glycosylation sites caused similar but much stronger effects. Immunocytochemical analysis of receptor localisation revealed that the amino-terminal domain but not the carbohydrates appear to be involved in the transport of the receptor polypeptide to the cell surface.     

Single amino acid substitution in constant region 1 or 4 of gp120 causes the phenotype of a human immunodeficiency virus type 1 variant with mutations in hypervariable regions 1 and 2 to revert.

The second major cysteine loop of human immunodeficiency virus type 1 envelope glycoprotein gp120 contains 5 to 11 consensus N-linked glycosylation sites, which is disproportionately higher than the number of such sites found in other regions of gp120. Amino acid substitutions introduced at three of six N-linked glycosylation sites in this region of an infectious molecular clone, HXB2, resulted in severe impairment of virus infectivity. Isolation and genetic characterization of a revertant of this mutant revealed an isoleucine-for-valine substitution at position 84 in constant region 1 and an isoleucine-for-methionine substitution at position 434 in constant region 4. Further mutational analysis indicated that either isoleucine substitution was sufficient to confer the revertant phenotype. These findings demonstrate that V1/V2 not only functionally interacts with C4, as previously reported, but also interacts with C1. The observation that compensatory changes do not involve regeneration of N-linked glycosylation sites in the second major cysteine loop suggests that replication of human immunodeficiency virus type 1 in vitro is independent of the presence of a disproportionate number of N-linked glycosylation sites within this loop.     

Asparagine-linked glycosylation of human chymotrypsin C is required for folding and secretion but not for enzyme activity

Human chymotrypsin C (CTRC) plays a protective role in the pancreas by mitigating premature trypsinogen activation through degradation. Mutations that abolish activity or secretion of CTRC increase the risk for chronic pancreatitis. The aim of the present study was to determine whether human CTRC undergoes asparagine-linked (N-linked) glycosylation and to examine the role of this modification in CTRC folding and function. We abolished potential sites of N-linked glycosylation (Asn-Xaa-Ser/Thr) in human CTRC by mutating the Asn residues to Ser individually or in combination, expressed the CTRC mutants in HEK 293T cells and determined their glycosylation state using PNGase F and endo H digestion. We found that human CTRC contains a single N-linked glycan on Asn52. Elimination of N-glycosylation by mutation of Asn52 (N52S) reduced CTRC secretion about 10-fold from HEK 293T cells but had no effect on CTRC activity or inhibitor binding. Overexpression of the N52S CTRC mutant elicited endoplasmic reticulum stress in AR42J acinar cells, indicating that N-glycosylation is required for folding of human CTRC. Despite its important role, Asn52 is poorly conserved in other mammalian CTRC orthologs, including the rat which is monoglycosylated on Asn90. Introduction of the Asn90 site in a non-glycosylated human CTRC mutant restored full glycosylation but only partially rescued the secretion defect. We conclude that N-linked glycosylation of human CTRC is required for efficient folding and secretion; however, the N-linked glycan is unimportant for enzyme activity or inhibitor binding. The position of the N-linked glycan is critical for optimal folding, and it may vary among the otherwise highly homologous mammalian CTRC sequences.     

Mutational analysis of conserved N-linked glycosylation sites of human immunodeficiency virus type 1 gp41.

Amino acid substitutions were introduced into four conserved N-linked glycosylation sites of the human immunodeficiency virus type 1 envelope transmembrane glycoprotein, gp41, to alter the canonical N-linked glycosylation sequences. One altered site produced a severe impairment of viral infectivity, which raises the possibility that N-linked sugars at this site may have an important role in the human immunodeficiency virus type 1 life cycle.     

N-linked glycosylation of the HIV type-1 gp120 envelope glycoprotein as a major determinant of CCR5 and CXCR4 coreceptor utilization

The variable V1V2 and V3 regions of the human immunodeficiency virus type-1 (HIV-1) envelope glycoprotein (gp120) can influence viral coreceptor usage. To substantiate this we generated isogenic HIV-1 molecularly cloned viruses that were composed of the HxB2 envelope backbone containing the V1V2 and V3 regions from viruses isolated from a patient progressing to disease. We show that the V3 amino acid charge per se had little influence on altering the virus coreceptor phenotype. The V1V2 region and its N-linked glycosylation degree were shown to confer CXCR4 usage and provide the virus with rapid replication kinetics. Loss of an N-linked glycosylation site within the V3 region had a major influence on the virus switching from the R5 to X4 phenotype in a V3 charge-dependent manner. The loss of this V3 N-linked glycosylation site was also linked with the broadening of the coreceptor repertoire to incorporate CCR3. By comparing the amino acid sequences of primary HIV-1 isolates, we identified a strong association between high V3 charge and the loss of this V3 N-linked glycosylation site. These results demonstrate that the N-linked glycosylation pattern of the HIV-1 envelope can strongly influence viral coreceptor utilization and the R5 to X4 switch.     

Specific N-linked and O-linked glycosylation modifications in the envelope V1 domain of simian immunodeficiency virus variants that evolve in the host alter recognition by neutralizing antibodies.

During progression to AIDS in simian immunodeficiency virus (SIV) Mne-infected macaques, viral variants are selected that encode sequences with serine and threonine changes in variable region 1 (V1) of the surface component of the viral envelope protein (Env-SU). Because these serine and threonine amino acid changes are characteristic of sites for O-linked and N-linked glycosylation, we examined whether they were targets for modification by carbohydrates. For this purpose, we used several biochemical methods for analyzing the Env-SU protein encoded by chimeras of SIVMneCL8 and envelope sequences cloned from an SIVMneCL8-infected Macaca nemestrina during clinical latency and just after the onset of AIDS. The addition of an N-linked glycan was demonstrated by changes in the electrophoretic mobility of Env-SU, and this was verified by specific glycanase digestions and a detailed analysis of the molecular mass of partially purified Env-SU by matrix-assisted laser desorption ionization time-of-flight mass spectrometry (MALDI-TOF MS). Molecular mass calculations by MALDI-TOF MS also demonstrated an increased mass, from 102.3 to 103.5 kDa, associated with serine and threonine residues predicted to be O-linked glycosylation sites. Together, these data provide the first direct evidence that the carbohydrate profile of Env-SU is distinct in SIV variants that evolve during infection of the host. Moreover, our studies show that these changes in glycosylation in V1 were directly associated with changes in antigenicity. Specifically, serine and threonine changes in V1 allowed the virus to escape neutralization by macaque sera that contained antibodies that could neutralize the parental virus, SIVMneCL8. The escape from antibody recognition appeared to be influenced by either O-linked or N-linked carbohydrate additions in V1. Moreover, when glycine residues were engineered at the positions where serine and threonine changes evolve in V1 of SIVMneCL8, there was no change in antigenicity compared to SIVMneCL8. This suggests that the amino acids in V1 are not part of the linear epitope recognized by neutralizing antibody. More likely, V1-associated carbohydrates mask the major neutralizing epitope of SIV. These experiments indicate that the selection of novel glycosylation sites in the V1 region of envelope during the course of disease is driven by humoral immune responses.     

Evaluation of human N-linked glycosylation sites in murine granulocyte-macrophage colony-stimulating factor.

Nonglycosylated murine and human granulocyte-macrophage colony-stimulating factor have a molecular mass of approximately 14.5 kDa predicted from the primary amino acid sequence. The expression of both proteins in COS cells leads to a heterogeneous population of molecules that differ in the degree of glycosylation. Both human and murine molecules contain two N-linked glycosylation sites that are situated in nonhomologous locations along the linear sequence. Despite this difference both proteins show a similar size distribution among the glycosylation variants. These studies analyze the effects of introducing in the murine protein novel N-linked glycosylation sites corresponding to those sites found in the human molecule. A panel of molecules composed of various combinations of human N-linked glycosylation sites in either the presence or the absence of murine N-linked glycosylation was compared. Substitution of a proper human N-linked glycosylation consensus sequence at Asn 24 did not result in N-linked glycosylation, nor was there any considerable effect on bioactivity. Replacement of the N-linked glycosylation consensus sequence at Asn 34 results in glycosylation similar to that found in the human molecule and causes a significant decrease in bioactivity. These data suggest that the position of N-linked glycosylation is critical for maximal bioactivity in a particular species and that the changes in position of these sites in different species probably occurred during evolution in response to changes in their receptors.     

The relevance of N-linked glycosylation to the binding of a ligand to guanylate cyclase C.

The role of carbohydrate moieties at the N-linked glycosylation sites of guanylate cyclase C (GC-C), a receptor protein for guanylin, uroguanylin and heat-stable enterotoxin, in ligand binding and structural stability was examined using site-directed mutagenesis of the putative N-linked glycosylation sites in the extracellular domain (ECD) of porcine GC-C. For this purpose, eight mutant proteins of ECD (N9A, N20A, N56A, N172A, N261A, N284A, N334A and N379A) and six mutant proteins of the complete GC-C (N9A, S11A, N172A, T174A, N379A and T381A) were prepared, in which Ala replaced Asn, Ser and Thr at the N-linked glycosylation consensus sites. All the mutant proteins showed a ligand-binding affinity (K(d)) similar to those of the wild-type proteins, although the deletion of a carbohydrate moiety at each of the N-linked glycosylation sites affected the ligand-binding ability of ECD or GC-C to some degree. However, the mutant proteins of ECD (N379A) and GC-C (N379A and T381A) showed considerably decreased binding ability in the context of maximum capacity (B(max)) to a ligand, despite the fact that the expression levels of these mutant proteins were nearly the same as the wild-type proteins. Moreover, the mutant protein of ECD (N379A) was considerably less stable to a denaturant. These results clearly indicate a crucial role for the carbohydrate moiety at N379, which is located near the transmembrane region, in structural stability, the ability to bind to a ligand and the cyclase catalytic activity of GC-C, and provide a route for the elucidation of the mechanism of the interaction between GC-C and a ligand.     

N-Linked Glycosylation of the Hemagglutinin Protein Influences Virulence and Antigenicity of the 1918 Pandemic and Seasonal H1N1 Influenza A Viruses

The hemagglutinin (HA) protein is a major virulence determinant for the 1918 pandemic influenza virus; however, it encodes no known virulence-associated determinants. In comparison to seasonal influenza viruses of lesser virulence, the 1918 H1N1 virus has fewer glycosylation sequons on the HA globular head region. Using site-directed mutagenesis, we found that a 1918 HA recombinant virus, of high virulence, could be significantly attenuated in mice by adding two additional glycosylation sites (asparagine [Asn] 71 and Asn 286) on the side of the HA head. The 1918 HA recombinant virus was further attenuated by introducing two additional glycosylation sites on the top of the HA head at Asn 142 and Asn 172. In a reciprocal experimental approach, deletion of HA glycosylation sites (Asn 142 and Asn 177, but not Asn 71 and Asn 104) from a seasonal influenza H1N1 virus, A/Solomon Islands/2006 (SI/06), led to increased virulence in mice. The addition of glycosylation sites to 1918 HA and removal of glycosylation sites from SI/06 HA imposed constraints on the theoretical structure surrounding the glycan receptor binding sites, which in turn led to distinct glycan receptor binding properties. The modification of glycosylation sites for the 1918 and SI/06 viruses also caused changes in viral antigenicity based on cross-reactive hemagglutinin inhibition antibody titers with antisera from mice infected with wild-type or glycan mutant viruses. These results demonstrate that glycosylation patterns of the 1918 and seasonal H1N1 viruses directly contribute to differences in virulence and are partially responsible for their distinct antigenicity.     

Role of N-linked glycans in a human immunodeficiency virus envelope glycoprotein: effects on protein function and the neutralizing antibody response

The envelope (Env) glycoprotein of human immunodeficiency virus (HIV) contains 24 N-glycosylation sites covering much of the protein surface. It has been proposed that one role of these carbohydrates is to form a shield that protects the virus from immune recognition. Strong evidence for such a role for glycosylation has been reported for simian immunodeficiency virus (SIV) mutants lacking glycans in the V1 region of Env (J. N. Reitter, R. E. Means, and R. C. Desrosiers, Nat. Med. 4:679-684, 1998). Here we used recombinant vesicular stomatitis viruses (VSVs) expressing HIV Env glycosylation mutants to determine if removal of carbohydrates in the V1 and V2 domains affected protein function and the generation of neutralizing antibodies in mice. Mutations that eliminated one to six of the sites for N-linked glycosylation in the V1 and V2 loops were introduced into a gene encoding the HIV type 1 primary isolate 89.6 envelope glycoprotein with its cytoplasmic domain replaced by that of the VSV G glycoprotein. The membrane fusion activities of the mutant proteins were studied in a syncytium induction assay. The transport and processing of the mutant proteins were studied with recombinant VSVs expressing mutant Env G proteins. We found that HIV Env V1 and V2 glycosylation mutants were no better than wild-type envelope at inducing antibodies neutralizing wild-type Env, although an Env mutant lacking glycans appeared somewhat more sensitive to neutralization by antibodies raised to mutant or wild-type Env. These results indicate significant differences between SIV and HIV with regard to the roles of glycans in the V1 and V2 domains.     

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.     

In vitro mutagenesis identifies a region within the envelope gene of the human immunodeficiency virus that is critical for infectivity.

Site-specific mutagenesis was used to introduce amino acid substitutions at the asparagine codons of four conserved potential N-linked glycosylation sites within the gp120 envelope protein of human immunodeficiency virus (HIV). One of these alterations resulted in the production of noninfectious virus particles. The amino acid substitution did not interfere with the synthesis, processing, and stability of the env gene polypeptides gp120 and gp41 or the binding of gp120 to its cellular receptor, the CD4 (T4) molecule. Vaccinia virus recombinants containing wild-type or mutant HIV env genes readily induced syncytia in CD4+ HeLa cells. These results suggest that alterations involving the second conserved domain of the HIV gp120 may interfere with an essential early step in the virus replication cycle other than binding to the CD4 receptor. In long-term cocultures of a T4+ lymphocyte cell line and colon carcinoma cells producing the mutant virus, revertant infectious virions were detected. Molecular characterization of two revertant proviral clones revealed the presence of the original mutation as well as a compensatory amino acid change in another region of HIV gp120.     

Partial glycosylation of Asn2181 in human factor V as a cause of molecular and functional heterogeneity. Modulation of glycosylation efficiency by mutagenesis of the consensus sequence for N-linked glycosylation.

Coagulation factor V (FV) circulates in two forms, FV1 and FV2, having slightly different molecular masses and phospholipid-binding properties. The aim was to determine whether this heterogeneity is due to the degree of glycosylation of Asn(2181). FVa1 and FVa2 were isolated and digested with endoglycosidase PNGase F. As judged by Western blotting, the FVa2 light chain contained two N-linked carbohydrates, whereas FVa1 contained three. Wild-type FV and three mutants, Asn(2181)Gln, Ser(2183)Thr, and Ser(2183)Ala, were expressed in COS1 cells, activated by thrombin, and analyzed by Western blotting. Wild-type FVa contained the 71 kDa-74 kDa doublet, whereas the Asn(2181)Gln and Ser(2183)Ala mutants contained only the 71 kDa light chain. In contrast, the Ser(2183)Thr mutant gave a 74 kDa light chain. This demonstrated that the third position in the Asn-X-Ser/Thr consensus affects glycosylation efficiency, Thr being associated with a higher degree of glycosylation than Ser. The Ser(2183)Thr mutant FVa was functionally indistinguishable from plasma-purified FVa1, whereas Asn(2181)Gln and Ser(2183)Ala mutants behaved like FVa2. Thus, the carbohydrate at Asn(2181) impaired the interaction between FVa and the phospholipid membrane, an interpretation consistent with a structural analysis of a three-dimensional model of the C2 domain and the position of a proposed phospholipid-binding site. In conclusion, we show that the FV1-FV2 heterogeneity is caused by differential glycosylation of Asn(2181) related to the presence of a Ser rather than a Thr at the third position in the consensus sequence of glycosylation.     

Functional role of N-linked glycosylation on the rat melanin-concentrating hormone receptor 1

Melanin-concentrating hormone (MCH) is known to act through two G-protein-coupled receptors MCHR1 and MCHR2. MCHR1 has three potential sites (Asn13, Asn16 and Asn23) for N-linked glycosylation in its extracellular amino-terminus which may modulate its reactivity. Site-directed mutagenesis of the rat MCHR1 cDNA at single or multiple combinations of the three potential glycosylation sites was used to examine the role of the putative carbohydrate chains on receptor activity. It was found that all three potential N-linked glycosylation sites in MCHR1 were glycosylated, and that N-linked glycosylation of Asn23 was necessary for full activity. Furthermore, disruption of all three glycosylation sites impaired proper expression at the cell surface and receptor activity. These data outline the importance of the N-linked glycosylation of the MCHR1.     

Mutational analysis of N-glycosylation recognition sites on the biochemical properties of Aspergillus kawachii alpha-L-arabinofuranosidase 54

A role for N-linked oligosaccharides on the biochemical properties of recombinant alpha-l-arabinofuranosidase 54 (AkAbf54) defined in glycoside hydrolase family 54 from Aspergillus kawachii expressed in Pichia pastoris was analyzed by site-directed mutagenesis. Two N-linked glycosylation motifs (Asn(83)-Thr-Thr and Asn(202)-Ser-Thr) were found in the AkAbf54 sequence. AkAbf54 comprises two domains, a catalytic domain and an arabinose-binding domain classified as carbohydrate-binding module 42. Two N-linked glycosylation sites are located in the catalytic domain. Asn(83), Asn(202), and the two residues together were replaced with glutamine by site-directed mutagenesis. The biochemical properties and kinetic parameters of the wild-type and mutant enzymes expressed in P. pastoris were examined. The N83Q mutant enzyme had the same catalytic activity and thermostability as the wild-type enzyme. On the other hand, the N202Q and N83Q/N202Q mutant enzymes exhibited a considerable decrease in thermostability compared to the glycosylated wild-type enzyme. The N202Q and N83Q/N202Q mutant enzymes also had slightly less specific activity towards arabinan and debranched arabinan. However, no significant effect on the affinity of the mutant enzymes for the ligands arabinan, debranched arabinan, and wheat and rye arabinoxylans was detected by affinity gel electrophoresis. These observations suggest that the glycosylation at Asn(202) may contribute to thermostability and catalysis.     

N-linked glycosylation of rabies virus glycoprotein. Individual sequons differ in their glycosylation efficiencies and influence on cell surface expression.

Many eukaryotic proteins are modified by N-linked glycosylation, a process in which oligosaccharides are added to asparagine residues in the sequon Asn-X-Ser/Thr. However, not all such sequons are glycosylated. For example, rabies virus glycoprotein (RGP) contains three sequons, only two of which appear to be glycosylated in virions. To examine further the signals in proteins which regulate N-linked core glycosylation, the glycosylation efficiencies of each of the three sequons in the antigenic domain of RGP were compared. For these studies, mutants were generated in which one or more sequons were deleted by site-directed mutagenesis. Core glycosylation of these mutants was studied using two independent systems: 1) in vitro translation in rabbit reticulocyte lysate supplemented with dog pancreatic microsomes, and 2) transfection into glycosylation-deficient Chinese hamster ovary cells. Parallel results were obtained with both systems, demonstrating that the sequon at Asn37 is inefficiently glycosylated, the sequons at Asn247 and Asn319 are efficiently glycosylated, and the glycosylation efficiency of each sequon is not influenced by glycosylation at other sequons in this protein. High levels of cell surface expression of RGP in Chinese hamster ovary cells are seen with any mutant containing an intact sequon at Asn247 or Asn319, whereas low levels of cell surface expression are seen when the sequon at Asn37 is present alone; deletion of all three sequons completely blocks RGP cell surface expression. Thus, although core glycosylation at Asn37 is inefficient, it is still sufficient to support a biological function, cell surface expression. Future studies using mutagenesis of this model protein and its expression in these two well defined systems will aim to begin to unravel the rules governing core glycosylation of glycoproteins.     

Thr but Asn of the N-glycosylation sites of PrP is indispensable for its misfolding

Prion protein (PrP) contains two N-linked glycosylation sites. It is unknown which amino acid substitution contributes most efficiently to the abolishment of N-linked glycosylations. To define the influence of amino acid substitution at the N-linked glycosylation sites on the conversion efficiency of mouse PrP, we tested each of all 19 amino acid substitutions at either one of the N-linked glycosylation sites (codon 180, 182, 196 or 198). The conversion efficiency of the mutagenized PrP was highly dependent on the newly introduced amino acid itself regardless of the absence of N-linked glycosylation in scrapie-infected mouse neuroblastoma cells. The majority of mutant PrP with substitutions at the Asn residues of the N-linked glycosylation sites were conversion-competent, whereas most mutant PrP with substitutions at the Thr residues were conversion-incompetent. These findings emphasize that the Asn residues of the N-linked glycosylation sites are replaceable to abolish N-linked glycosylations without directly affecting the protein function.     

Mutational analysis of N-linked glycosylation sites of Friend murine leukemia virus envelope protein.

The roles played by the N-linked glycans of the Friend murine leukemia virus envelope proteins were investigated by site-specific mutagenesis. The surface protein gp70 has eight potential attachment sites for N-linked glycan; each signal asparagine was converted to aspartate, and mutant viruses were tested for the ability to grow in NIH 3T3 fibroblasts. Seven of the mutations did not affect virus infectivity, whereas mutation of the fourth glycosylation signal from the amino terminus (gs4) resulted in a noninfectious phenotype. Characterization of mutant gene products by radioimmunoprecipitation confirmed that glycosylation occurs at all eight consensus signals in gp70 and that gs2 carries an endoglycosidase H-sensitive glycan. Elimination of gs2 did not cause retention of an endoglycosidase H-sensitive glycan at a different site, demonstrating that this structure does not play an essential role in envelope protein function. The gs3- mutation affected a second posttranslational modification of unknown type, which was manifested as production of gp70 that remained smaller than wild-type gp70 after removal of all N-linked glycans by peptide N-glycosidase F. The gs4- mutation decreased processing of gPr80 to gPr90, completely inhibited proteolytic processing of gPr90 to gp70 and Pr15(E), and prevented incorporation of envelope products into virus particles. Brefeldin A-induced mixing of the endoplasmic reticulum and parts of the Golgi apparatus allowed proteolytic processing of wild-type gPr90 to occur in the absence of protein transport, but it did not overcome the cleavage defect of the gs4- precursor, indicating that gs4- gPr90 is resistant to the processing protease. The work reported here demonstrates that the gs4 region is important for env precursor processing and suggests that gs4 may be a critical target in the disruption of murine leukemia virus env product processing by inhibitors of N-linked glycosylation.