Interaction of Sindbis virus glycoproteins during morphogenesis.

In cells infected with the Sindbis temperature-sensitive mutants ts-23 and ts-10 (complementation group D), which contain a defect in the envelope glycoprotein E1, the precursor polypeptide PE2 is not cleaved to the envelope glycoprotein E2 at the nonpermissive temperature. This defect is phenotypically identical to the defect observed in the complementation group E mutant, ts-20. The lesion in ts-23 is reversible upon shift to permissive temperature, whereas that of ts-10 is not. Antiserum against whole virus, E1, or E2 also prevents the cleavage of PE2 in cells infected with wild-type Sindbis virus. Because the cleavage of PE2 is inhibited by the lesion in mutants that are genotypically distinct and by anti-E1 or -E2 serum, it appears that PE2 and E1 exist as a complex in the membrane of the infected cell.     

Identification of immunologically cross-reactive proteins of Sindbis virus: evidence for unique conformation of E1 glycoprotein from infected cells

Hyperimmune antisera to purified Sindbis (SIN) or Semliki Forest (SF) virus were used to identify alphavirus-specific and cross-reactive proteins in virions and infected cells. The hyperimmune sera participated in homologous and cross-cytolysis of alphavirus-infected cells, and the use of monospecific antisera to SIN structural proteins suggested that E1 and E2 could serve as target proteins in cytolysis. Proteins from purified virions or infected cells were extracted with Nonidet P-40, denatured by procedures for sodium dodecyl sulfate-polyacrylamide gel electrophoresis, transferred to nitrocellulose solid supports, and reacted with hyperimmune sera and 125I-labeled protein A (immunoblotting on denatured proteins). Alternatively, native proteins extracted by mild Nonidet P-40 treatment were precipitated with hyperimmune sera before denaturation by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. After immunoblotting, homologous antiserum reacted with the virus structural proteins E1, E2, capsid extracted from purified virions, and the counterparts of these proteins extracted from infected cells. In addition, PE2 and a 92,000-molecular-weight protein from infected cells reacted with homologous antiserum. These proteins were also immunoprecipitated with homologous antiserum. After immunoblotting, the Sindbis capsid protein was shown to be cross-reactive whether derived from purified virions or from infected cells; no cross-reactivity was observed with PE2 or E2 from either source, and the E1 glycoprotein was shown to be cross-reactive only when obtained from virions. However, the E1 glycoprotein could be cross-immunoprecipitated from infected cells (as well as from disrupted virions), and, in addition, capsid and a 92,000-molecular-weight protein were cross-immunoprecipitated from infected cells. These results suggest that a native conformation of the cell-associated E1 glycoproteins may be required for immunological cross-reactivity (immune precipitation), whereas virion but not cell-associated E1 retains immunological cross-reactivity after denaturation (immunoblot technique). The findings extend our previously published evidence which suggested that alphavirus maturation is accompanied by a change in immunological cross-reactivity with respect to E1.     

Sindbis virus attachment: isolation and characterization of mutants with impaired binding to vertebrate cells.

Sindbis virus can infect a broad range of insect and vertebrate cell types. The ability to restrict tissue tropism and target virus infection to specific cell types would expand the usefulness of engineered alphaviruses as gene expression vectors. In this study, virus pools derived from libraries of full-length Sindbis virus cDNA clones containing random insertion mutations in the PE2 or E1 virion glycoprotein gene were screened for mutants defective for binding to vertebrate cells. Binding-competent mutants were depleted by serial adsorption to chicken embryo fibroblast (CEF) monolayers at 4 degrees C, and the remaining population was amplified by immune-enhanced infection of P388D1 cells. From the PE2 libraries, 12 candidate mutants showing reduced cytopathic effects on CEF monolayers were isolated and three representative mutants, NB1, NB2, and NB12, were characterized in detail. Insertion mutations for NB1 and NB12 were found near the PE2 cleavage site, whereas the insertion in NB2 occurred between residues 69 and 74 of E2. Although virion assembly and release occurred normally for all three mutants, PE2 cleavage was completely (NB1) or partially (NB12) blocked for the mutants with insertions near the PE2 cleavage site. Both NB1 and NB2 were defective for binding to CEF and BHK-21 cells. Mild trypsin digestion of isolated NB1 virions resulted in PE2 cleavage and partially restored binding to CEF. Besides defective binding, NB1 also exhibited slower CEF penetration kinetics. Consistent with previous work, these results implicate PE2 cleavage and domains in the N-terminal portion of E2 as important determinants of alphavirus binding and penetration. Binding-defective mutants such as NB2, which exhibit normal particle assembly, release, and penetration, may be useful for future efforts to target Sindbis virus infection.     

Chemical cross-linking of proteins of Semliki Forest virus: virus particles and plasma membranes from BHK-21 cells treated with colchicine or dibucaine.

Chemical cross-linking of the proteins of Semliki Forest virus has been performed in virus particles and in baby hamster kidney-21 (BHK-21) cells infected with Semliki Forest virus. Most of the studies were done with the reversible cross-linkers dimethyl 3,3'-thiobis(propionimidate) and dithiobis(succinimidyl propionate). The identity of the cross-linked species was determined by two-dimensional electrophoresis. The results with virus particles showed extensive cross-linking of the nucleocapsid proteins and the formation of dimers of the two large envelope glycoproteins (E1 and E2). Similar patterns for the cross-linked virus proteins were observed in plasma membranes isolated from BHK-21 cells infected with Semliki Forest virus. No cross-linking of the third envelope glycoprotein (E3) was observed. Also, there was no evidence for significant cross-linking between host and virus proteins. The addition of colchicine, a drug that disrupts microtubules, to infected BHK-21 cells had no effect on the cross-linking of virus proteins in the plasma membrane. In contrast, dibucaine, a local anesthetic, greatly inhibited the formation of envelope dimers (E1-E2) in plasma membranes, but not in virus particles. The implication of these results for the involvement of the cytoskeletal system in the morphogenesis of Semliki Forest virus is discussed.     

Replication of Sindbis Virus IV. Electron Microscope Study of the Insertion of Viral Glycoproteins into the Surface of Infected Chick Cells

The appearance of Sindbis virus-envelope glycoproteins in the surfaces of chicken embryo fibroblasts was studied by an indirect labeling technique. This technique involved treating infected cells sequentially with rabbit immunoglobulin G (IgG) specific for Sindbis virus followed by hemocyanin-conjugated goat (anti-rabbit IgG) IgG; surface replicas of these cells were then prepared and examined in the electron microscope. As early as 2 h after infection (and at least 1 h before mature virions were released), newly synthesized virus-envelope glycoproteins were detected at the cell surface. By 3 h after infection, cell surface membranes were extensively modified by the insertion of the Sindbis glycoproteins. When infected cells were prefixed with glutaraldehyde before labeling, the glycoproteins were distributed fairly evenly over the cell surface, although a slight clustering was observed on cells labeled early in infection. However, no evidence for large-scale clustering of virus glycoproteins corresponding to patches of budding virus was observed. Similar results were found with unfixed cells labeled at 4 C. However, when unfixed cells were labeled at 37 C, the glycoproteins were shown to be in discrete clusters, demonstrating that these glycoprotein antigens can diffuse laterally through the cell membrane at this temperature.     

Envelope antigens of Sindbis virus in cells infected with temperature-sensitive mutants.

Indirect fluorescent-antibody studies of living and fixed chick cells infected with temperature-sensitive mutants of Sindbis virus suggest that functional envelope glycoprotein E1 must be inserted through the plasma membrane before E2. PE2 and E2 do not affect the insertion of E1. The experiments also suggest that normal PE2, a glycosylated precursor to E2, reacts with anti-E2 serum; the abnormal PE2 made by a temperature-sensitive PE2 cleavage-defective mutant did not. Abnormal E1 proteins made by E1-defective mutants also failed to react with anti-E1 serum.     

Fluorescence photobleaching recovery measurements reveal differences in envelopment of sindbis and vesicular stomatitis viruses

Fluorescence photobleaching recovery (FPR) measurements of virus glycoproteins on the surfaces of cells infected with vesicular stomatitis virus (VSV) and Sindbis virus showed that the VSV glycoprotein (G) remained mobile throughout the infectious cycle, whereas Sindbis virus glycoproteins (E1, E2) were partially mobile early after infection and immobile at later times when greater amounts of these proteins were on the cell surface. A highly mobile fraction of Sindbis virus glycoproteins was detected throughout the replication cycle of a temperature-sensitive mutant unable to form virus particles. Thus immobilization of E1 and E2 was the result of increasing surface glycoprotein concentrations and virus budding. Together with other data, which included the detection of E1 and E2 in particles as soon as these proteins were transported to the cell surface, the FPR results suggest that Sindbis virus assembly initiates on intracellular vesicles, where glycoproteins aggregate and bind nucleocapsids. In contrast, our FPR data on VSV support a model previously suggested by others, in which a small fraction of cell-surface G is immobilized into budding sites formed by interactions with virus matrix and nucleoproteins. FPR measurements also provide direct evidence for strong interactions between E1 and E2, as well as between E1 and PE2, the precursor form of E2.     

Two small virus-specific polypeptides are produced during infection with Sindbis virus.

We have identified and characterized two small virus-specific polypeptides which are produced during infection of cells with Sindbis virus, but which are not incorporated into the mature virion. The larger of these is a glycoprotein with an approximate molecular weight of 9,800 and is found predominantly in the medium of infected cells. Three independent lines of evidence demonstrate conclusively that this 9,800-dalton glycoprotein is produced during the proteolytic conversion of the precursor polypeptide, PE2, to the virion glycoprotein E2. This small glycoprotein is therefore analogous to the virion glycoprotein E3 of the very closely related alphavirus, Semliki Forest virus. The 9,800-dalton glycoprotein of Sindbis virus, unlike the E3 glycoprotein of Semliki Forest virus, is not, however, present in the viral particle. The other virus-specific polypeptide is 4,200 daltons in size, does not appear to be a glycoprotein, and is neither incorporated into the mature virus nor released into the culture medium. The gene for this small polypeptide is present in the viral 26S mRNA (the mRNA which encodes all the viral structural polypeptides) and appears to be located in the portion of the mRNA which encodes the two viral glycoproteins. The possibility that this 4,200-dalton polypeptide functions as a signal peptide during the synthesis of the viral membrane glycoproteins is discussed.     

Envelopment of Sindbis Virus: Synthesis and Organization of Proteins in Cells Infected with Wild Type and Maturation-Defective Mutants

The synthesis and organization of Sindbis virus structural proteins was investigated in BHK cells infected with wild-type virus (SVHR) or temperature-sensitive (ts) mutants defective in maturation. Cells infected with ts-23 or ts-20 (complementation groups D and E) were similar in the polypeptides synthesized at the nonpermissive temperature and differed from SVHR-infected cells in that the envelope protein E2 was not cleaved from the PE2 precursor. Data from experiments utilizing pulse-chase procedures or protein synthesis inhibitors indicated that although infectious virions were released from cells infected with these mutants in shift-down experiments, the particles were produced almost exclusively from proteins synthesized after the return to permissive temperature. This suggests that a stable complex may be formed among the structural proteins before budding. A membrane fraction isolated from cells infected with either ts mutants or SVHR contained the PE2, E1, and C polypeptides, whereas E2 was restricted to fractions obtained from SVHR-infected cells. Although equivalent amounts of virus-specific protein were synthesized in cells infected with either mutant and the cells contained qualitatively the same proteins in the isolated membranes, cells infected with ts-23 did not have virus-specific proteins exposed on their surface that could be detected by ferritin-conjugated antibody-labeling procedures or lactoperoxidase-mediated iodination. In contrast, ts-20-infected cells had significant amounts of viral protein, mainly E1, that could be detected on the plasma membrane by either procedure. Iodine was incorporated into E1 and E2 on the surface of SVHR-infected cells in the same relative amounts as seen in iodinated virions. PE2, however, although present in membranes, could not be iodinated on the surface of infected cells under any of the conditions used in this study. We also monitored the relative efficiency with which these viral proteins could be removed from intact cells by dilute solutions of nonionic detergents. The results indicated that E2 was most efficiently removed, followed by E1. PE2 (the precursor to E2) and C remained associated with the cell and could be subsequently isolated in the membrane fraction.     

Structural rearrangement of infecting Sindbis virions at the cell surface: mapping of newly accessible epitopes.

Sindbis virus glycoproteins E1 and E2 undergo a conformational alteration during early virus-cell interaction at the cell surface (D. Flynn, W. J. Meyer, J. M. MacKenzie, Jr., and R. E. Johnston, J. Virol. 64:3643-3653, 1990). Certain epitopes normally internal on native virus become accessible to monoclonal antibody (MAb) binding after attachment but before internalization of virus particles. These newly exposed epitopes, termed transitional epitopes, may be part of functionally important domains made accessible at the surface of the altered virus to facilitate entry into cells. Heating Sindbis virions at 51 degrees C for a short time induced a similar, although not identical, exposition of transitional epitopes on the E1 and E2 glycoproteins (W. J. Meyer, S. Gidwitz, V. K. Ayers, R. J. Schoepp, and R. E. Johnston, J. Virol. 66:3504-3513, 1992). In the current report, we have identified several of the transitional epitopes that become exposed as a consequence of early virus-cell interactions. Transitional epitope MAbs that bound to rearranged, heated virions and virus-cell complexes were used in antibody competition binding assays on heated Sindbis virions to map the spatial relationships between native, external, neutralizing antigenic sites and newly exposed transitional epitopes. Because the heated, rearranged particles retained their infectivity, MAbs that bound to transitional epitopes also were used to isolate MAb neutralization escape mutants. Sequencing the glycoprotein genes of the escape mutants identified specific E1 and E2 loci where mutation prevented MAb binding to transitional epitopes. One of the transitional epitopes identified (E2 residues 200 to 202) lies in the E2 190-216 region, which harbors two major neutralization sites, E2a and E2b, and an N-linked glycosylation site at E2 196. The glycosylation signal was eliminated by site-directed mutagenesis of a full-length cDNA clone of the Sindbis virus genome. The absence of a carbohydrate moiety did not expose the transitional epitopes mapped to this locus, suggesting that on native virions, the inaccessibility of the E2 200-202 determinant was inherent in the structure of the glycoprotein spike.     

Subunit composition of the membrane glycoprotein complex of Semliki Forest virus

The quaternary structure of the membrane glycoproteins E1, E2 and E3 of Semliki Forest virus has been determined in intact virus and in the protein complexes obtained after Triton X100 solubilization. Intact and solubilized virus were treated with a cleavable cross-linking reagent and the covalently cross-linked glycoprotein complexes were isolated and characterized using antibodies specific for the E1 and E2 membrane glycoproteins. The isolation and characterization procedure was done in a low sodium dodecyl sulphate concentration which prevented non-covalent association between glycoprotein species, but did not abolish antigen-antibody binding.The major glycoprotein complex seen after cross-linking of either intact or Triton X100 solubilized virus was an approximately 100,000 molecular weight species composed of E1-E2 heterodimers only. These findings show that E1 and E2 form a complex in the virus and that this complex is retained after solubilization with Triton X100. The smallest membrane glycoprotein E3 was not cross-linked to the other proteins and was therefore lost in the isolation procedure. However, the presence of E3 together with E1 and E2 in complexes obtained after Triton X100 solubilization of intact virus suggests that an E1-E2-E3 trimer is present in the virus. It is likely that this trimer forms the spike-like structures seen on the surface of the virus.We have observed that antibody specific for one component of the virus glycoprotein complex can induce rearrangement of uncross-linked complexes in Triton X100 solubilized form. This fact should be considered when using specific antibody for characterization of protein complexes.     

Cross-linking of glycoprotein oligomers during herpes simplex virus type 1 entry.

Herpes simplex virus (HSV) has 10 glycoproteins in its envelope. Glycoprotein B (gB), gC, gD, gH, and gL have been implicated in virus entry. We previously used chemical cross-linking to show that these five glycoproteins were close enough to each other to be cross-linked into homodimeric and hetero-oligomeric forms; hetero-oligomers of gB-gC, gC-gD, gD-gB, gH-gL, gC-gL and gD-gL were found in purified virions. To better understand the roles of these glycoproteins in viral entry, we have modified a standard HSV penetration assay to include cross-linkers. This allowed us to examine changes in associations of viral glycoproteins during the entry process. HSV-1(KOS) was adsorbed at 4 degrees C to human neuroblastoma cells (SY5Y). The temperature was raised to 37 degrees C and cells were treated with cross-linker at various times after the temperature shift. Cytoplasmic extracts were examined by Western blotting (immunoblotting) for viral glycoproteins. We found that (i) as in virus alone, the length and concentration of the cross-linking agent affected the number of specific complexes isolated; (ii) the same glycoprotein patterns found in purified virions were also present after attachment of virions to cells; and (iii) the ability to cross-link HSV glycoproteins changed as virus penetration proceeded, e.g., gB and gD complexes which were present during attachment disappeared with increasing time, and their disappearance paralleled the kinetics of penetration. However, this phenomenon appeared to be selective since it was not observed with gC oligomers. In addition, we examined the cross-linking patterns of gB and gD in null viruses K082 and KOSgD beta. Neither of these mutants, which attach but cannot penetrate, showed changes in glycoprotein cross-linking over time. We speculate that these changes are due to conformational changes which preclude cross-linking or spatial alterations which dissociate the glycoprotein interactions during the penetration events.     

Inhibition of Sindbis virus maturation after treatment of infected cells with trypsin.

Brief treatment of Sindbis virus-infected BHK-21 or Vero cells with low concentrations of trypsin irreversibly blocked further production of progeny virions after removal of the enzyme. The inhibitory effects of the trypsin treatment could only be demonstrated in cells in which virus infection was established; optimal inhibition occurred at ca. 3 h postinfection. Production of virus structural proteins PE2, E1, and C occurred at normal levels in inhibited cells. PE2 and E1 were also transported to the cell plasma membrane during inhibition; however, PE2 was not cleaved to E2, and little capsid protein became membrane associated relative to control cells. Although trypsin treatment had no effect on Sindbis protein synthesis, the production of both 26S and 42S RNA was greatly reduced. Similar trypsin treatment of BHK cells infected with vesicular stomatitis virus had no detectable effect on the course of virus infection.     

Restricted replication of two alphaviruses in ricin-resistant mouse L cells with altered glycosyltransferase activities.

Two mouse L cell variant lines (CL 3 and CL 6) selected for resistance to the toxic plant lectin ricin were restricted in their ability to replicate the two alphaviruses Sindbis virus and Semliki Forest virus. CL 3 cells have been shown to exhibit increased CMP-sialic acid:glycoprotein sialyltransferase and GM3 synthetase activities, whereas CL 6 cells have been shown to contain decreased UDPgalactose:glycoprotein galactosyltransferase and UDP-N-acetylglucosamine:glycoprotein N-acetylglucosaminyltransferase activities. The adsorption of Sindbis virus to CL 6 cells was considerably reduced, suggesting that the loss or inaccessibility of the receptors for Sindbis virus accounted for a major defect in virus production in these cells. In contrast, CL 3 synthesized Sindbis viral RNA and proteins but were unable to convert the precursor glycoprotein PE2 to the structural protein E2. The cleavage of PE2 to E2 was also blocked in both CL 3 and CL 6 cells infected with Semliki Forest virus.     

The Furin Protease Cleavage Recognition Sequence of Sindbis Virus PE2 Can Mediate Virion Attachment to Cell Surface Heparan Sulfate

Cell culture-adapted Sindbis virus strains attach to heparan sulfate (HS) receptors during infection of cultured cells (W. B. Klimstra, K. D. Ryman, and R. E. Johnston, J. Virol. 72:7357-7366, 1998). At least three E2 glycoprotein mutations (E2 Arg 1, E2 Lys 70, and E2 Arg 114) can independently confer HS attachment in the background of the consensus sequence Sindbis virus (TR339). In the studies reported here, we have investigated the mechanism by which the E2 Arg 1 mutation confers HS-dependent binding. Substitution of Arg for Ser at E2 1 resulted in a significant reduction in the efficiency of PE2 cleavage, yielding virus particles containing a mixture of PE2 and mature E2. Presence of PE2 was associated with an increase in HS-dependent attachment to cells and efficient attachment to heparin-agarose beads, presumably because the furin recognition site for PE2 cleavage also represents a candidate HS binding sequence. A comparison of mutants with partially or completely inhibited PE2 cleavage demonstrated that efficiency of cell binding was correlated with the amount of PE2 in virus particles. Viruses rendered cleavage defective due to deletions of portions or all of the furin cleavage sequence attached very poorly to cells, indicating that an intact furin cleavage sequence was specifically required for PE2-mediated attachment to cells. In contrast, a virus containing a partial deletion was capable of efficient binding to heparin-agarose beads, suggesting different requirements for heparin bead and cell surface HS binding. Furthermore, virus produced in C6/36 mosquito cells, which cleave PE2 more efficiently than BHK cells, exhibited a reduction in cell attachment efficiency correlated with reduced content of PE2 in particles. Taken together, these results strongly argue that the XBXBBX (B, basic; X, hydrophobic) furin protease recognition sequence of PE2 can mediate the binding of PE2-containing Sindbis viruses to HS. This sequence is very similar to an XBBXBX heparin-HS interaction consensus sequence. The attachment of furin protease cleavage sequences to HS may have relevance to other viruses whose attachment proteins are cleaved during maturation at positively charged recognition sequences.     

Effect of low-NaCl medium on the envelope glycoproteins of Sindbis virus

Lowering the NaCl concentration of the medium inhibits the release of Sindbis virus from infected chicks cells at a stage after the nucleocapsids have bound to the membranes of the infected cells. The failure of trypsin treatment to release the inhibited virus and the ratio of the proteins in the inhibited cells make it seem likely that the inhibited virus is all intracellular. Experiments using antisera specific for E1 and E2, the envelope glycoproteins of Sindbis, suggest that the inhibitory effect of low-salt medium is mediated through an effect on E2. Lactoperoxidase radioiodination experiments indicate that, even when cleaved from PE2, E2 is not exposed on the surface of low-NaCl-treated chick cells.     

Polycaryocyte formation mediated by Sindbis virus glycoproteins.

The process of cell fusion mediated by Sindbis virus membrane proteins synthesized after infection was examined. At the times after infection at which virus proteins were detectable on the cell surface, Sindbis virus-infected BHK-21 cells were found to express a fusion function after brief treatment at acid pH. In studies employing wild-type virus and temperature-sensitive mutants and testing drug or protease inhibition of virus production, we made the following observations on Sindbis virus-mediated fusion from within. (i) Fusion requires the synthesis of virus glycoproteins and their transport to the cell surface. (ii) Modification of the cell plasma membrane by polypeptides PE2 and E1 alone is not sufficient for expression of the fusion function. (iii) The proteolytic conversion of plasma membrane-associated PE2 to E2 is not essential for fusion. (iv) Glycosylation of virus plasma membrane proteins is essential for fusion. (v) The lesions of Sindbis virus temperature-sensitive mutants do not affect their ability to fuse cells.     

Sindbis virus mutations which coordinately affect glycoprotein processing, penetration, and virulence in mice

Rapid penetration of baby hamster kidney cells was used as a selective pressure for the isolation of pathogenesis mutants of the S.A.AR86 strain of Sindbis virus. Unlike most Sindbis virus strains, S.A.AR86 is virulent in adult as well as neonatal mice. Two classes of mutants were defined. One class was attenuated in adult mice inoculated intracerebrally as well as in neonatal mice inoculated either intracerebrally or subcutaneously. Sequence analysis of the glycoprotein genes of the parent virus and three such mutant strains revealed a single point mutation which resulted in an amino acid change at position 1 in the E2 glycoprotein. The change from a serine in S.A.AR86 to an asparagine in the mutants created a new site for N-linked glycosylation which appeared to be utilized. This mutation did not retard release of infectious particles; however, mutant virions contained the E2 precursor protein (PE2) rather than the E2 glycoprotein itself. The mutants also lost the ability to bind two E2-specific monoclonal antibodies, R6 and R13. A second class of mutants was attenuated in neonatal mice upon subcutaneous inoculation but remained virulent in adults and in neonates when inoculated intracerebrally. Sequence analysis of three such strains revealed the substitution of an arginine residue for a serine at position 114 in the E2 glycoprotein. Reactivity with monoclonal antibodies R6 and R13 was reduced, yet members of this mutant class were more susceptible than S.A.AR86 to neutralization by these antibodies.     

Surface expression of viral glycoproteins is polarized in epithelial cells infected with recombinant vaccinia viral vectors.

In polarized epithelial cells, maturation sites of enveloped viruses that form by budding at cell surfaces are restricted to particular membrane domains. Recombinant vaccinia viruses were used to investigate the sites of surface expression in the Madin-Darby canine kidney (MDCK) cell line of the hemagglutinin (HA) of influenza virus, the G glycoprotein of vesicular stomatitis virus (VSV), and gp70/p15E of Friend murine leukemia virus (MuLV). These glycoproteins could be demonstrated by immunofluorescence on the surfaces of MDCK cells as early as 4 h post-infection. In intact MDCK monolayers, vaccinia recombinants expressing HA produced a pattern of surface fluorescence typical of an apically expressed glycoprotein. In contrast, cells infected with vaccinia recombinants expressing VSV-G or MuLV gp70/p15E exhibited surface fluorescence only when monolayers were treated with EGTA to disrupt tight junctions, as expected of glycoproteins expressed on basolateral surfaces. Immunoferritin labeling in conjunction with electron microscopy confirmed that MDCK cells infected with the HA recombinant exhibited specific labeling of the apical surfaces whereas the VSV-G and MuLV recombinants exhibited the respective antigens predominantly on the basolateral membranes. Quantitation of surface expression by [125I]protein A binding assays on intact and EGTA-treated monolayers confirmed the apical localization of the vaccinia-expressed HA and demonstrated that 95% of the VSV-G and 97% of the MuLV gp70/p15E glycoproteins were localized on the basolateral surfaces. These results demonstrate that glycoproteins of viruses that normally mature at basolateral surfaces of polarized epithelial cells contain all of the structural information required for their directional transport to basolateral plasma membranes.