From the Institut de Biologie de Lille (IFR3), Institut Pasteur de Lille, 59021 Lille, France and § Laboratory of Fundamental Virology, Institute of Pathology, University of Liège, B-4000 Liège, Belgium
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ABSTRACT |
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The varicella-zoster virus (VZV) is the etiological agent of two different human pathologies, chickenpox (varicella) and shingles (zoster). This alphaherpesvirus is believed to acquire its lipidic envelope in the trans-Golgi network (TGN). This is consistent with previous data showing that the most abundant VZV envelope glycoprotein gE accumulates at steady-state in this organelle when expressed from cloned cDNA. In the present study, we have investigated the intracellular trafficking of gI, another VZV envelope glycoprotein. In transfected cells, this protein shows a very slow biosynthetic transport to the cell surface where it accumulates. However, upon co-expression of gE, gI experiences a dramatic increase in its exit rate from the endoplasmic reticulum, it accumulates in a sialyltransferase-positive compartment, presumably the TGN, and cycles between this compartment and the cell surface. This differential behavior results from the ability of gE and gI to form a complex in the early stages of the biosynthetic pathway whose intracellular traffic is exclusively determined by the sorting information in the tail of gE. Thus, gI provides the first example of a molecule localized to the TGN by means of its association with another TGN protein. We also show that, during the early stages of VZV infection, both proteins are also found in the TGN of the host cell. This suggests the existence of an intermediate stage during VZV biogenesis in which the envelope glycoproteins, transiently arrested in the TGN, could promote the envelopment of newly synthesized nucleocapsids into this compartment and, therefore, the assembly of infective viruses.
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INTRODUCTION |
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The trans-Golgi network (TGN)1 is a tubuloreticular compartment located on the trans-most side of the Golgi complex (1). This organelle houses different proteins that are involved in adding post-translational modifications to polypeptides traveling along the secretory pathway. In addition, this organelle constitutes the main sorting station in the secretory pathway (2, 3). The TGN can undergo rapid tubularization and mixing with endosomal compartments in the presence of the fungal metabolite brefeldin A (BFA) (4).
The TGN has also been used by certain viruses as a membrane donor for their lipidic envelope (envelopment or budding process), as it happens in the case of the varicella-zoster virus (VZV) (5, 6). VZV is a human alphaherpesvirus causing chickenpox (varicella), as a result of the primary infection, and shingles (zoster) upon reactivation of the latent virus (7, 8). As it occurs in other alphaherpesviruses, the VZV nucleocapsids are assembled in the nuclei of the infected cells. These nucleocapsids are then released into the periplasmic space by budding through the inner nuclear membrane, thereby acquiring a transient envelope that is lost upon fusion with the outer nuclear membrane. In this way, the nucleocapsids are released in the cytosol, where they acquire a second and definitive envelope. This envelope is derived from the TGN, as initially demonstrated by Gershon et al. (5) by examining VZV-infected cells at the ultrastructural level. Mature viruses accumulate finally in an intracellular endosomal compartment (9).
As happens in other cases of viruses that undergo intracellular assembly, envelopment of VZV in the TGN requires that the corresponding envelope glycoproteins have to be delivered to this compartment during viral infection (10-12). This implies that sorting signals must exist within these glycoproteins to ensure their correct targeting, making these molecules very useful tools for analyzing the mechanisms involved in TGN localization. We and others have recently shown that the most abundant envelope glycoprotein of VZV (gpI or gE) accumulates in the TGN when expressed from cloned cDNA and that this accumulation results, at least partially, from its ability to be rapidly retrieved form the cell surface (10-12). The sorting information in the sequence of gE has been mapped to its cytoplasmic tail, and shown to consist of two tyrosine-containing tetrapeptides related to endocytosis motifs (11, 12) and a more C-terminal acidic cluster that contains casein-kinase II- phosphorylatable residues (11, 12). These signals are similar to those found in other molecules known to be localized in the TGN at steady state, such as TGN38 or furin (13-19).
In addition to gE, there are at least five additional glycoproteins in the envelope of VZV (gB, gH, gI, gC, and gL, formerly known as gpII, gpIII, gpIV, gpV, and gpVI, respectively) (20), whose sequences are apparently devoid of TGN-sorting information. If VZV indeed acquires its final envelope in the TGN, then mechanisms must exist to ensure that all these molecules reach this compartment in order to promote infective VZV formation. In the present article, we have focused our attention on another type I glycoprotein of the viral envelope, the glycoprotein gI (or gpIV). This molecule has been shown to physically interact with gE in VZV (21), as well as in herpes simplex virus (HSV-1) (22), feline herpesvirus (FHV-1) (23), and pseudorabies virus (PRV) (24), three other members of the alphaherpesvirinae subfamily. Our results indicate that gI, which is found in the cell surface when expressed alone, accumulates in the TGN when expressed together with gE. This accumulation of gI in the TGN also relies on its rapid internalization from the cell surface. Our data indicate that gE and gI precursors can form a stoichiometric complex in the endoplasmic reticulum (ER), which results in an increased maturation rate of gI. We have also found that, in VZV-infected cells, both gE and gI can be found shortly after infection in a perinuclear compartment that most likely corresponds to the TGN.
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EXPERIMENTAL PROCEDURES |
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Materials-- Monoclonal antibodies SG1 and SG4, against VZV gE and gI, respectively, were obtained from Viro Research Inc. (Rockford, IL). The polyclonal serum against the cytoplasmic tail of furin was generously provided by Dr. W. Garten (University of Marburg, Marburg, Germany). The SA48 HeLa clone stably expressing VSVG-tagged sialyltransferase (ST-VSVG) was a generous gift of Dr. Tommy Nilsson (EMBL, Heidelberg, Germany). All secondary antibodies against the Fc of mouse or rabbit IgGs coupled to FITC or rhodamine were purchased from Dianova (Hamburg, Germany).
Cloning of the VZV Envelope Glycoproteins gE and gI in Mammalian Expression Vectors-- Construction of the gE expression vector has been previously described (12). In order to clone VZV gI, the complete open reading frame was amplified from a lysate of VZV (Dumas strain)-infected cells using the Expand High Fidelity kit (Boehringer Mannheim, Mannheim, Germany). The resulting fragment was digested with XbaI and HindIII and was cloned into the same sites of the eukaryotic expression vector pSFFV6 (25), or downstream the T7 promoter in pGEM1.
Construction of gE-KK and -SS Mutants-- The gE mutants containing the cytoplasmic tail of the yeast protein Wbp1p with either the C-terminal KKXX or the SSXX signals were constructed by polymerase chain reaction-based amplification using reverse primers in which the corresponding sequences of the wild-type or mutated Wbp1p cytoplasmic tails had been introduced as translational fusions with the sequence of the gE transmembrane domain. The resulting polymerase chain reaction fragments were digested with XbaI and HindIII and cloned into the same sites in the pSFFV6 vector. The sequences of both mutants were verified using the Sanger dideoxy chain termination method.
Antibody Generation-- The antibody 1667 against the full-length gE was obtained by cloning a cDNA fragment coding for the mature VZV gE open reading frame with a hexahistidine tag at the C terminus into the NcoI/BamHI sites of the pET15b vector (Novagen, Wiesbaden, Germany). The protein was expressed in BL21 cells and the insoluble fraction (containing most of the recombinant gE) was solubilized in 8 M urea and loaded on a Talon metal-affinity column (CLONTECH, Heidelberg, Germany). After extensive washing, the bound protein was eluted with SDS-loading buffer, and approximately 50 µg were loaded on a 7.5% preparative SDS-polyacrylamide gel. The part of the gel containing the recombinant protein was excised, homogenized using a Teflon-glass homogenizer, mixed with either Freund's complete or incomplete adjuvant, and used to immunize rabbits following standard procedures.
To produce the 2679 antibody against the cytoplasmic tail of gI, a fragment comprising amino acids 314-354 of the gI precursor form was cloned into the pGEX-4T-1 vector (Pharmacia, Freiburg, Germany) as a fusion to glutathione S-transferase. The glutathione S-transferase-gI fusion was expressed in XL-1 Blue cells and purified by affinity chromatography on a glutathione-Sepharose column (Pharmacia, Freiburg, Germany), following the manufacturer's instructions. After elution, the fusion protein was loaded on a preparative 7.5% preparative SDS-polyacrylamide gel. The gel fragment containing the band was excised, homogenized, mixed with Freund's adjuvant, and used to inoculate rabbits following a standard immunization schedule. The serum was affinity-purified by incubation with a nitrocellulose strip onto which the recombinant glutathione S-transferase-gI had been previously bound (26).Antibody Uptake--
For the internalization assays, a
continuous uptake was performed in which transfected cells seeded on
coverslips were washed with prewarmed -MEM and overlaid with 200 µl of complete
-MEM in which the antibodies had been diluted as
specified in the figure legends. After 1-h incubation, the
internalization medium was removed and the cells were immediately fixed
and processed for immunofluorescence using fluorescein or
rhodamine-coupled secondary antibodies.
VZV Infection--
Due to the cell-associated nature of
VZV, infections were carried out as described previously (27), by
co-culture of VZV (Ellen strain)-infected Vero cells with noninfected
either Vero or HeLa cells. For the immunofluorescence experiments,
infected and noninfected cells were plated on coverslips at a 1:4 ratio and grown in complete -MEM for different times as indicated in the
figure legends. The cells were subsequently fixed and processed for
immunofluorescence.
Miscellaneous-- Published procedures were used for vaccinia T7 infection (12), metabolic labeling of the cells and immunoprecipitation (28), and for calcium-phosphate transient transfection and indirect immunofluorescence (12).
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RESULTS |
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The Subcellular Localization of gI Depends on the Simultaneous Expression of gE-- To address the subcellular localization of the VZV-envelope glycoprotein gI (gpIV), we have cloned the complete gI open reading frame in the mammalian expression vector pSFFV6 (25). We have used this construct to perform transient transfection assays in HeLa cells followed by immunofluorescence using anti-gI-specific antibodies. This experiment revealed that, in every transfected cell, gI was exclusively found at the cell surface (Fig. 1b). As a control, we also performed transient transfections with an analogous construct in which the complete gE (gpI) open reading frame had been inserted into the same expression vector (12). In agreement with previous data (12), in cells transfected with the gE expression vector, this protein was exclusively localized in the perinuclear region of the cell (Fig. 1c), in a compartment that has been previously identified as the TGN, based on its co-localization at the light microscopy level with the TGN markers TGN38, furin, and sialyltransferase (12), at the electron microscopic level with galactosyltransferase,2 and by its sensitivity to BFA and nocodazole, two drugs that affect the morphology of this compartment (12).
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Intracellular Distribution and Traffic of gI in the Presence of gE-- The colocalization experiments shown above indicate that, when expressed together, gE and gI are localized to the same cellular compartment, but they do not prove that this compartment is indeed the TGN, the organelle where gE accumulates when expressed alone (10-12). We have previously used the rapid tubularization in response to BFA as a hallmark of the TGN to distinguish it from other membrane-bound compartments clustered in the perinuclear region of the cell (12). When HeLa cells expressing gE and gI were treated for 5 min with 10 µg/ml BFA, fixed and decorated with anti-gE and anti-gI antibodies, both molecules were found to colocalize in thin tubules that emanated from the perinuclear region into the cell periphery (Fig. 2, a and b), strongly suggesting that the TGN is the compartment where gE and gI accumulate upon co-expression.
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Localization of gI in Cells Expressing an ER Resident Form of
gE--
The results presented so far suggest that gE and gI are found
within a complex in the cell whose traffic and distribution is solely
determined by the sorting information in the cytoplasmic tail of gE. To
verify this hypothesis, we constructed a modified version of gE in
which its cytoplasmic tail had been replaced by that of the yeast
protein Wbp1p, a type-I membrane protein that forms part of the ER
resident oligosaccharyl-transferase complex (32). The tail of Wbp1p,
which contains a consensus KKXX ER retention motif, has been
shown to be sufficient to confer ER localization to reporter molecules
both in mammalian and yeast cell systems (33, 34). When the
gE-KKXX and the gI expression constructs were simultaneously
transfected into HeLa cells and the localization of both molecules was
assessed by indirect immunofluorescence, both the gE-KKXX
chimera and gI were found in a cytoplasmic reticular compartment
showing all the morphological features of the ER (Fig. 3, a and b). As a
control, we also constructed a gE-SSXX expression plasmid,
in which the two lysines at positions 3 and
4 in the KKXX signal have been replaced by serines. This mutation is
known to abolish the ER retention capacity of the KKXX motif
(33). As expected, in cells co-expressing the gE-SSXX mutant
and gI, both molecules were only detected at the cell surface (Fig. 3, c and d). These result confirms our prediction
that the intracellular traffic of gI is exclusively determined by the
sorting information on the tail of gE, presumably as a reflect of their
association in the early secretory pathway.
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Effect of gE on the Maturation of gI-- We then asked whether the expression of one given protein could influence the maturation of the other. In order to address this question, gE and gI were expressed either alone or simultaneously in HeLa cells with the help of a T7 RNA-polymerase recombinant vaccinia virus. The cells were metabolically labeled with radioactive methionine, chased for increasing periods of time, and lysed, and the lysates were immunoprecipitated with anti-gE- and anti-gI-specific antibodies. To identify the precursor and mature forms of gE and gI, both molecules were immunoprecipitated from cells lysates that were obtained either immediately after the labeling period or after 6 h of chase. The results showed that gE was initially synthesized as a 70-kDa band that was converted during the chase to a 100-kDa polypeptide, and gI was initially found as a 50-kDa band that matured to yield a fuzzy 65-kDa band (Fig. 4a). These values are in agreement with those found by other groups, either in transfected (21, 35) or in VZV-infected cells (36), for both the precursor and mature forms of gE and gI. When gE was expressed alone, immunoprecipitation with anti-gE antibodies revealed that maturation of the protein occurred rather rapidly, since as early as 20 min after initiation of the chase, almost 50% of the labeled 70-kDa precursor molecule was converted to the mature 100-kDa form (Fig. 4, b and c). When gI was expressed alone and immunoprecipitated with anti-gI antibodies under analogous conditions, its processing occurred very slowly, requiring more than 1 h to convert only 20% of the precursor to the mature form (Fig. 4, b and c). However, when gE and gI were expressed together, processing of gI was considerably enhanced, because 50% of the mature form could be detected after only 40 min of chase (Fig. 4, b and c). Under the same conditions, no difference was observed in the maturation of gE, when compared with the results obtained when this protein was expressed alone (Fig. 4b). In addition, the anti-gE- and anti-gI-specific antibodies failed to immunoprecipitate any gI and gE, respectively (data not shown).
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Localization of gE and gI in VZV-infected Cells-- We then investigated the localization of gE and gI in cells infected with VZV. This virus is extremely cell-associated when propagated in cultured cells and therefore, infections must be performed by co-culture of noninfected with already infected cells. An additional difficulty was the unavailability of antibodies able to recognize endogenous TGN markers in a susceptible host cell line (Vero cells are a convenient host for VZV). To circumvent this problem, we undertook a double approach. First, we cultured VZV-infected Vero cells with noninfected Vero cells and used these cells to determine by immunofluorescence the localization of gE and gI. Second, VZV-infected Vero cells were co-cultured with a HeLa clone that stably expresses a VSV-G epitope-tagged version of sialyltransferase (37). The results obtained using both approaches are shown in Fig. 5.
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DISCUSSION |
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In the present work, we show that, in cells transfected with gE and gI, two different glycoproteins of the VZV envelope, both molecules localize to the TGN. A similar situation is also observed in VZV-infected cells during the early stages of infection. Our data also indicate that gE and gI form a complex in the early stages of the secretory pathway. This is supported by the following evidences. First, the expression of an ER resident form of gE (the gE-KKXX mutant) leads to the accumulation of gI in this compartment. Second, gE and gI can be coimmunoprecipitated shortly after their synthesis as precursor forms containing nonprocessed oligosaccharides (data not shown) (21). For this reason, it should be expected that the interaction between these two proteins would occur directly through their polypeptide backbones. In this regard, Yao et al. (21) have mapped a cysteine-rich highly conserved region in the ectodomain of gE (amino acids 342-446), whose deletion leads to a substantial decrease in the yield of co-immunoprecipitation with gI. In addition, the gE·gI complex seems to contain equimolar amounts of both components. Coimmunoprecipitation experiments show that radiolabeled gE and gI exhibit similar intensity, as it could be expected for two molecules containing similar proportion of sulfur-containing amino acids. Besides, when the expression level of gI is higher than that of gE (for instance, using mammalian expression vectors with different promoters), only a small fraction of the total gI can leave the ER in association with gE (data not shown).
According to all these data, the most likely scenario is that gE, by interacting with gI, facilitates its folding and, consequently, accelerates its release from the ER quality control system. Similar situations have been previously described for the homologous complexes from three other alphaherpesviruses, PRV (24), BHV-1 (38), and FHV-1 (23, 39). In cells infected with different alphaherpesviruses, it has been reported that processing of gE is impaired in the absence of gI (23, 24, 38) and, in at least one of them, gE was found by immunofluorescence to remain in the ER in the absence of gI (23). However, it has been recently shown that, in cells infected with a gI-deleted VZV strain, glycosylation and intracellular delivery of gE can occur normally (40).
After association in the ER, gE, and gI reach the TGN, where they are found at steady state. The localization of this complex results from a rapid recycling between the TGN and the plasma membrane. Since gI is devoid of sorting information, the targeting to the TGN and the recycling of the gE·gI complex must solely rely on the sorting signals found in tail of gE (12, 41). The association of viral envelope glycoproteins to form hetero-oligomers that are transported according to the sorting information found in just one of the glycoproteins is a well known mechanism to ensure co-segregation of viral glycoproteins. This situation can be found, for example, in the viruses of the bunyavirus family, whose budding occurs in the Golgi complex (42). In this case, the G2 envelope glycoprotein, which is found in the cell surface when expressed alone (43), can be targeted to the Golgi complex by forming an heterodimer with the G1 glycoprotein (44), which contains a Golgi-retention signal (45). A similar example is provided by the rubella virus, whose E1 glycoprotein is targeted to the Golgi via its interaction with E2 (46). The interaction between VZV gE and gI constitutes, to our knowledge, the first example of such a mechanism for localization to the TGN. The fact that complex formation between gE and gI occurs not only in VZV (21, 36), but also in their homologues from HSV-1 (22), PRV (47), FHV-1 (23), and BHV-1 (38), suggests that our findings illustrate a common feature for all alphaherpesviruses.
We have observed that the localization of gE and gI to the TGN occurs not only in cells expressing both proteins from cloned cDNAs, but also in VZV-infected cells. This finding provides additional support to the idea that this organelle plays an essential role in VZV assembly (5). However, in VZV-infected cells, the gE·gI complex also appears in cytoplasmic vesicles devoid of any TGN markers. These structures could correspond to the previously described intracellular vacuoles that originate as a result of the viral infection and that have been proposed to constitute the major sites of VZV virion accumulation (48). Similar structures were also shown to be accessible to endocytic tracers and to contain gE and mannose 6-phosphate receptor immunoreactivity (9). According to these properties, the gE- and gI-positive structures detected in VZV-infected cells would correspond to endocytic compartments, to which VZV could have access by means of the interaction in the TGN between the mannose 6-phosphate receptors and its envelope glycoproteins (that have been shown to contain mannose 6-phosphate modifications (9). In this way, mature viruses could be packaged into clathrin-coated vesicles and subsequently delivered to endocytic compartments in the same way as are lysosomal enzymes (49). This could agree with morphological studies illustrating the budding of nucleocapsids in the TGN (5).
How do all these data on the intracellular trafficking of the gE·gI complex agree with the current knowledge on its function and localization? The available information suggests that both components of the VZV gE·gI complex (or of the homologous complexes from HSV-1 and PRV) are dispensable for viral entry, replication, and release of new viruses (50-52). However, these two proteins seem to be required for direct cell-to-cell spread of the corresponding viruses, as suggested by studies performed with alphaherpesviruses bearing deletions in the gE or gI genes (50, 52-60). The mechanism underlying the process of direct cell-to-cell spread remains largely uncharacterized, although it probably involves direct fusion of cell membranes. In the case of VZV, direct cell-to-cell spread seems to be the only productive way of infection when the virus is propagated in cultured cells, since secreted viruses appear to be non-infective (9, 61, 62). Earlier studies have reported that both gE glycoproteins and the gE·gI complexes from VZV (35, 63) and HSV-1 (64) display Fc binding activity, although this activity is not present in every member of the subfamily (38, 47). Therefore, the gE·gI could interact with plasma membrane receptors that contain domains belonging to the immunoglobulin superfamily and, in this way, promote cell fusion and consequently, contribute to the direct cell-to-cell spread. Since appearance of the gE·gI complex at the cell surface seems to be restricted to the late stages of infection, we hypothesize that the gE·gI complex could have a dual role during VZV biogenesis. (i) During the early stages of infection, the expression of gE and gI would be kept at low levels. As a consequence, the complex would remain in the TGN. Under these conditions, the gE·gI complex, most likely functioning together with the other envelope glycoproteins, could promote recruitment of the nucleocapsids and, therefore, contribute to the formation of mature viruses at the TGN (5). (ii) During the late stages of infection, expression of gE and gI would reach much higher levels, which would then lead to the appearance of the complex at the cell surface. This situation would therefore resemble the results obtained by other groups when using strong promoters to express gE and gI in transient transfections (21, 35) and would simply reflect the known mislocalization of TGN molecules to the cell surface upon overexpression (12, 15, 19, 65-67). At this stage, the gE·gI complex, as a consequence of its appearance on the cell surface, could interact with receptors in neighboring noninfected cells and contribute to cell-to-cell spread.
In summary, we have characterized the intracellular traffic of the complex formed by two of the VZV envelope glycoproteins, gE and gI, and we have provided evidence that this complex traffics in an identical manner both in double-transfected as in VZV-infected cells. This complex is found mainly at steady-state at the TGN, which provides further support to the idea that this organelle plays an essential role during VZV assembly. Future studies will be aimed to characterize the intracellular transport of other VZV envelope glycoproteins as well as to identify putative viral-encoded factors that could control this process.
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ACKNOWLEDGEMENTS |
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We thank Dr. R. LeBorgne for critical reading of the manuscript and J.-M. Merchez for the photographic artwork.
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FOOTNOTES |
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* This work was partially supported by the European Community (HCM ERB-CHRTXCT-940592) and the association "Vaincre les Maladies Lysosomales."The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
Supported by a fellowship from the CNRS. Present address:
Biozentrum der Universität Basel, Klingerbergstrasse 70, 4056 Basel, Switzerland.
¶ To whom correspondence should be addressed: Institut de Biologie de Lille, 1, Rue du Professeur Calmette, 59021 Lille, France. Tel.: (33)320871025; Fax: (33)320871019; E-mail: Bernard.Hoflack{at}pasteur-lille.fr.
1 The abbreviations used are: TGN, trans-Golgi network; BFA, brefeldin A; BHV, bovine herpesvirus; ER, endoplasmic reticulum; FHV, feline herpesvirus; HSV, herpes simplex virus; PRV, pseudorabies virus; ST, sialyltransferase; VZV, varicella-zoster virus; FITC, fluorescein isothiocyanate; TRITC, tetrahodamine isothiocyanate; MEM, minimum Eagle's medium; VSV-G, vesicular stomatitis virus glycoprotein G.
2 A. Alconada, S. Röttgers, and B. Hoflack, unpublished observations.
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REFERENCES |
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