Host cell-dependent differences in the oligosaccharide moieties of the VSV G protein

Establishing Rules for Self-Adhesion and Aggregation of N-Glycan Sugars Using Virus Glycan Shields

The surfaces of cells and pathogens are covered with short polymers of sugars known as glycans. Complex N-glycans have a core of three mannose sugars with distal repeats of N-acetylglucosamine and galactose sugars terminating with sialic acid (SA). Long-range tough and short-range brittle self-adhesions were observed between SA and mannose residues, respectively, in ill-defined artificial monolayers. We investigated if and how these adhesions translate when the residues are presented in N-glycan architecture with SA at the surface and mannose at the core and with other glycan sugars. Two pseudotyped viruses with complex N-glycan shields were brought together in force spectroscopy (FS). At higher ramp rates, slime-like adhesions were observed between the shields, whereas Velcro-like adhesions were observed at lower rates. The higher approach rates compress the virus as a whole, and the self-adhesion between the surface SA is sampled. At the lower ramp rates, however, the complex glycan shield is penetrated and adhesion from the mannose core is accessed. The slime-like and Velcro-like adhesions were lost when SA and mannose were cleaved, respectively. While virus self-adhesion in forced contact was modulated by glycan penetrability, the self-aggregation of the freely diffusing virus was only determined by the surface sugar. Mannose-terminal viruses self-aggregated in solution, and SA-terminal ones required Ca2+ ions to self-aggregate. Viruses with galactose or N-acetylglucosamine surfaces did not self-aggregate, irrespective of whether or not a mannose core was present below the N-acetylglucosamine surface. Well-defined rules appear to govern the self-adhesion and -aggregation of N-glycosylated surfaces, regardless of whether the sugars are presented in an ill-defined monolayer, or N-glycan, or even polymer architecture.

Surface modification via strain-promoted click reaction facilitates targeted lentiviral transduction

As a result of their ability to integrate into the genome of both dividing and non-dividing cells, lentiviruses have emerged as a promising vector for gene delivery. Targeted gene transduction of specific cells and tissues by lentiviral vectors has been a major goal, which has proven difficult to achieve. We report a novel targeting protocol that relies on the chemoselective attachment of cancer specific ligands to unnatural glycans on lentiviral surfaces. This strategy exhibits minimal perturbation on virus physiology and demonstrates remarkable flexibility. It allows for targeting but can be more broadly useful with applications such as vector purification and immunomodulation.

A study of the glycoproteins of Autographa californica nuclear polyhedrosis virus (AcNPV)

Pulse labeling with tritiated mannose was used to follow the time course of Autographa californica nuclear polyhedrosis virus (AcNPV) glycoprotein synthesis in Spodoptera frugiperda IPLB-21 cells. Nine viral-induced intracellular glycoproteins were first detected from as early as 2 hr postinoculation (67K, early phase) to as late as 14 hr (36K and 19K glycoproteins, intermediate phase). Glycosylation of these proteins was observed to continue to the end of the experiment (28 hr postinoculation). Seven of these intracellular glycoproteins could also be detected in infected Trichoplusia ni TN-368 cells 24 hr postinoculation. When the glycosylation inhibitor tunicamycin was present (from 0 hr postinoculation) there was no detectable glycosylation of any of these viral-induced glycoproteins. Metabolic labeling of the nonoccluded virus budded from IPLB-21 and TN-368 with tritiated mannose or N-acetylglucosamine identified 11 structural glycoproteins, 8 of which were identical in both virus preparations. All of these structural glycoproteins were sensitive to the inhibitory action of tunicamycin. A single 42K structural glycoprotein was detected (with acetylglucosamine only) in the occluded form of AcNPV. Glycosylation of this structural protein appeared to be insensitive to tunicamycin. Lactoperoxidase-catalyzed radioiodination was used to determine which of the virus structural glycoproteins are exposed on the virion surface.

Control of carbohydrate processing: the lec1A CHO mutation results in partial loss of N-acetylglucosaminyltransferase I activity

Lec1 CHO cell glycosylation mutants are defective in N-acetylglucosaminyltransferase I (GlcNAc-TI) activity and therefore cannot convert the oligomannosyl intermediate (Man5GlcNAc2Asn) into complex carbohydrates. Lec1A CHO cell mutants have been shown to belong to the same genetic complementation group but exhibit different phenotypic properties. Evidence is presented that lec1A represents a new mutation at the lec1 locus resulting in partial loss of GlcNAc-TI activity. Structural studies of the carbohydrates associated with vesicular stomatitis virus grown in Lec1A cells (Lec1A/VSV) revealed the presence of biantennary and branched complex carbohydrates as well as the processing intermediate Man5GlcNAc2Asn. By contrast, the glycopeptides from virus grown in CHO cells (CHO/VSV) possessed only fully processed complex carbohydrates, whereas those from Lec1/VSV were almost solely of the Man5GlcNAc2Asn intermediate type. Therefore, the Lec1A glycosylation phenotype appears to result from the partial processing of N-linked carbohydrates because of reduced GlcNAc-TI action on membrane glycoproteins. Genetic experiments provided evidence that lec1A is a single mutation affecting GlcNAc-TI activity. Lec1A mutants could be isolated at frequencies of 10(-5) to 10(-6) from unmutagenized CHO cell populations by single-step selection, a rate inconsistent with two mutations. In addition, segregants selected from Lec1A X parental cell hybrid populations expressed only Lec1A or related lectin-resistant phenotypes and did not include any with a Lec1 phenotype. The Lec1A mutant should be of interest for studies on the mechanisms that control carbohydrate processing in animal cells and the effects of reduced GlcNAc-TI activity on the glycosylation, translocation, and compartmentalization of cellular glycoproteins.

Control of carbohydrate processing: the lec1A CHO mutation results in partial loss of N-acetylglucosaminyltransferase I activity

Lec1 CHO cell glycosylation mutants are defective in N-acetylglucosaminyltransferase I (GlcNAc-TI) activity and therefore cannot convert the oligomannosyl intermediate (Man5GlcNAc2Asn) into complex carbohydrates. Lec1A CHO cell mutants have been shown to belong to the same genetic complementation group but exhibit different phenotypic properties. Evidence is presented that lec1A represents a new mutation at the lec1 locus resulting in partial loss of GlcNAc-TI activity. Structural studies of the carbohydrates associated with vesicular stomatitis virus grown in Lec1A cells (Lec1A/VSV) revealed the presence of biantennary and branched complex carbohydrates as well as the processing intermediate Man5GlcNAc2Asn. By contrast, the glycopeptides from virus grown in CHO cells (CHO/VSV) possessed only fully processed complex carbohydrates, whereas those from Lec1/VSV were almost solely of the Man5GlcNAc2Asn intermediate type. Therefore, the Lec1A glycosylation phenotype appears to result from the partial processing of N-linked carbohydrates because of reduced GlcNAc-TI action on membrane glycoproteins. Genetic experiments provided evidence that lec1A is a single mutation affecting GlcNAc-TI activity. Lec1A mutants could be isolated at frequencies of 10(-5) to 10(-6) from unmutagenized CHO cell populations by single-step selection, a rate inconsistent with two mutations. In addition, segregants selected from Lec1A X parental cell hybrid populations expressed only Lec1A or related lectin-resistant phenotypes and did not include any with a Lec1 phenotype. The Lec1A mutant should be of interest for studies on the mechanisms that control carbohydrate processing in animal cells and the effects of reduced GlcNAc-TI activity on the glycosylation, translocation, and compartmentalization of cellular glycoproteins.

Unusual heterogeneity in the glycosylation of the G protein of the hazelhurst strain of vesicular stomatitis virus

The asparagine-linked oligosaccharides of the G protein of the Hazelhurst subtype of the New Jersey serotype of vesicular stomatitis virus (VSV) have been compared with the oligosaccharides from the G protein of the well-characterized Indiana serotype of VSV, with baby hamster kidney cells in monolayer culture as the host for both viruses. [3H]Glucosamine- and [3H]mannose-labeled glycopeptides from the G protein of purified virus were analyzed by the combined techniques of endo-beta-N-acetylglucosaminidase H (ENDO-H) digestion, concanavalin A and lentil lectin affinity chromatography, and Bio-Gel P-4 chromatography. Although almost all of the Indiana G protein oligosaccharides were acidic-type structures, as expected from previous studies; the Hazelhurst G protein contained a mixture of acidic-type, hybrid-type containing sialic acid, and neutral-type (predominantly Man5-6GlcNAc2-Asn) structures. The vast majority of acidic-type oligosaccharides from both the Hazelhurst and Indiana G proteins were diantennary structures, with less than half containing fucose linked to the innermost N-acetylglucosamine. Additional analysis of the Hazelhurst G protein by ENDO-H digestion and gel electrophoresis suggested that some of the mature G polypeptides contained acidic-type structures at both glycosylation sites, whereas the remainder contained an ENDO-H-resistant, acidic-type structure at one site and an ENDO-H-sensitive, hybrid- or neutral-type structure at the other site.

Infectivity and glycoprotein processing of herpes simplex virus type 1 grown in a ricin-resistant cell line deficient in N-acetylglucosaminyl transferase I

We report on the replication of herpes simplex virus type 1 (HSV-1) and viral glycoprotein processing in RicR14 cells, a mutant ricin-resistant cell line defective in N-acetylglucosaminyl transferase I activity. In these cells HSV-1(MP) and (F) replicated to yields very similar to those in parental BHK cells. The kinetics of HSV-1 adsorption in mutant and in parent cells was also essentially identical. Progeny virions from ricin-resistant and wild-type cells displayed comparable specific infectivities. However, in the mutant cells the efficiency of plating of progeny virus from both RicR14 and BHK cells was reduced. HSV-1(MP) failed to induce syncytia in RicR14 cells either in a plaque assay or after a high-multiplicity infection. Moreover, the fully glycosylated forms of glycoproteins (gB, gC, and gD) were totally absent, and only the partially glycosylated precursors (pgC, pgD. and a triplet in the gB-gA region) accumulated in HSV-1-infected ricin-resistant cells and in herpesvirions made in these cells. Consistent with these results analysis of pronase glycopeptides from cells labeled with [14C]glucosamine showed a strong decrease of sialylated complex-type oligosaccharides and a dramatic accumulation of the neutral mannose-rich chains. The latter chains predominate in partially glycosylated precursors, whereas the complex acidic chains predominate in the fully processed forms of HSV glycoproteins. These results taken together indicate that (i) host-cell N-acetylglucosaminyl transferase I participates in the processing of HSV glycoproteins; and (ii) infectivity of herpesvirions does not necessarily require the mature form of gB. The absence of HSV-1(MP)-induced fusion in RicR14 cells is discussed.