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Journal of Virology, June 2000, p. 5083-5090, Vol. 74, No. 11
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Pseudorabies Virus Glycoprotein K Requires the UL20
Gene Product for Processing
Petra
Dietz,1
Barbara G.
Klupp,1
Walter
Fuchs,1
Bernd
Köllner,2
Emilie
Weiland,3 and
Thomas
C.
Mettenleiter1,*
Institutes of Molecular
Biology1 and Diagnostic
Virology,2 Friedrich-Loeffler-Institutes,
Federal Research Centre for Virus Diseases of Animals, D-17498 Insel
Riems, and Institute of Immunology, Federal Research Centre for
Virus Diseases of Animals, D-72076
Tübingen,3 Germany
Received 21 December 1999/Accepted 16 March 2000
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ABSTRACT |
Glycoprotein K (gK) of pseudorabies virus (PrV) has recently been
identified as a virion component which is dispensable for viral entry
but required for direct cell-to-cell spread. Electron microscopic data
suggested a possible function of gK in virus egress by preventing
immediate fusion of released virus particles with the plasma membrane
(B. G. Klupp, J. Baumeister, P. Dietz, H. Granzow, and T. C. Mettenleiter, J. Virol. 72:1949-1958, 1998). For more detailed
analysis, a PrV mutant with a deletion of the UL53 (gK) open reading
frame (ORF) from codons 48 to 275 was constructed, and the protein was
analyzed with two monoclonal antibodies directed against PrV gK. The
salient findings of this report are as follows. (i) From the PrV UL53
ORF, a functional gK is translated only from the first in-frame
methionine. From the second in-frame methionine, a nonfunctional
product is expressed which is not incorporated into virions. (ii) When
constitutively expressed in a stable cell line without other viral
proteins, gK is only incompletely processed. After superinfection with
gK-deletion mutants, proper processing is restored and mature gK is
incorporated into virions. (iii) The UL20 gene product is specifically
required for processing of gK. gK is not correctly processed in a UL20
deletion mutant of PrV, and superinfection of gK-expressing cells with
PrV-UL20
does not restore processing. However, all other
known structural viral glycoproteins appear to be processed normally in
PrV-UL20-infected cells. (iv) Coexpression of gK and UL20
restored gK processing at least partially. Thus, our data show that the
UL20 gene product is required for proper processing of PrV gK.
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INTRODUCTION |
Herpesvirus glycoproteins, which are
localized in the virion envelope, play a major role in virus entry by
mediating attachment of virions to cell-surface receptors and fusion of
the viral envelope with the plasma membrane during penetration. They
are also involved in virus egress and direct cell-to-cell spread
(36). In addition, they represent prominent targets for the
host's immune response (29). For Pseudorabies
virus (PrV), a member of the Varicellovirus genus of
the Alphaherpesvirinae, 11 glycoproteins have been described which are designated as gB, gC, gD, gE, gG, gH, gI, gK, gL, gM, and gN
(30). Homologs for these proteins have also been found in
other alphaherpesviruses.
Mature glycoprotein K (gK) of PrV is a hydrophobic protein of 36 kDa
which is present in virions and contains both high-mannose as well as
complex forms of N-linked glycans (25). The protein is
conserved among the alphaherpesviruses, and homologous proteins or open
reading frames (ORFs) have also been described for herpes simplex virus
types 1 and 2 (HSV-1 and -2), bovine herpesvirus 1, equine herpesvirus
1, varicella-zoster virus (VZV), infectious laryngotracheitis virus,
and Marek's disease virus (12, 17, 20, 32, 34, 35, 39). All
deduced gK homologous proteins are characterized by the presence of
four hydrophobic domains of sufficient length to be membrane spanning.
The secondary structure of HSV-1 gK has been determined by in vitro
translation and processing of mutant proteins followed by protease
digestion (31). The results indicated that only three of the
four predicted hydrophobic domains indeed span the lipid bilayer. The
third hydrophobic domain probably forms a loop which is anchored by the
second and fourth hydrophobic domains.
First studies indicated that HSV-1 gK is involved in cell fusion, since
various mutations leading to a syncytial phenotype mapped to the UL53
gene which encodes gK (5, 7, 13, 33). These syn
mutations are preferentially located in the proposed ectodomains of gK
(31). Whereas HSV-1 gK had so far only been detected in the
endoplasmic reticulum and nuclear membranes of infected cells
(14), it has been found in virions of PrV and VZV (25,
32). Detailed studies of HSV-1, PrV, and VZV demonstrated an
important role for gK in virus replication (8, 15, 25, 32).
Only small plaques or foci of infected cells were observed after
infection of noncomplementing cells with gK mutants of HSV-1 and PrV
(14, 25), and productive viral replication was prevented by
deletion of VZV gK (32). Generally, the yield of gK mutants from noncomplementing cells is decreased compared to that of wild-type viruses, although final titers may depend on the cell type and particular virus mutant (14, 16).
HSV-1 and PrV gKs have been implicated in virus morphogenesis and
egress. In cells infected with HSV-1 F-gK
, which contains a
lacZ expression cassette within the UL53 ORF numerous
nonenveloped capsids were found in the cytoplasm (14),
whereas in cells infected with a gK-deletion mutant of strain KOS,
enveloped virions appeared to accumulate in the cytoplasm
(16). These findings pointed to an important role for HSV-1
gK in nucleocapsid envelopment and efficient transport of enveloped
virions to the extracellular space. Ultrastructural studies of a PrV gK
mutant also revealed a defect in virus egress. Whereas only a few
enveloped virions were detected outside of noncomplementing cells
infected with the mutant virus, numerous nucleocapsids were observed
just underneath the plasma membrane as well as fusion events which were
interpreted as immediate entry of virions into the cell they just left
(25). Thus, it was postulated that gK prevents entry of
released virus particles by inhibition of fusion between the virion
envelope and cytoplasmic membrane of infected cells (25).
Based on the model of gK topology (31), different functional
domains for gK involved in nucleocapsid envelopment, membrane fusion,
virus replication, and egress have been proposed (8). Effects on virus yield, plaque formation, and virus envelopment were
tentatively assigned to amino-terminal portions of gK, comprising the N
terminus, a cytoplasmic loop, and the second extracellular domain. The
cytoplasmic tail was dispensable for virus replication and egress. In
addition, comparison of gK sequences of various alphaherpesviruses
identified conserved cysteine-rich and tyrosine-based motifs. Mutation
of these motifs identified two domains of HSV-1 gK
the first
cytoplasmic domain and the extracellular loopwhich are crucial for
virus replication and egress, while the N terminus was correlated with
aberrant nucleocapsid envelopment and membrane fusion.
Besides gK, other putative multiply-membrane-spanning proteins include
the product of the UL20 gene. The presumably nonglycosylated HSV-1 UL20
protein was detected in nuclear membranes and Golgi-derived vesicles of
infected cells as well as in purified virions (38). Deletion
of the HSV-1 UL20 gene affects viral egress in a cell-type-specific manner which correlates with fragmentation of the Golgi apparatus (1). After infection of Vero cells with an HSV-1
UL20-deletion mutant, virus particles accumulated in the perinuclear
space (1, 2). Moreover, smaller amounts of viral
glycoproteins gC and gD were found in the plasma membrane, and immature
forms of both glycoproteins were present in enveloped virions, which
indicates that the HSV-1 UL20 protein contributes to processing and
transport of viral glycoproteins gC and gD from the
trans-Golgi area to the plasma membrane (1). The
PrV UL20 protein was also implicated in virus egress (10).
However, in ultrastructural analyses, mutation of the UL20 protein led
to accumulation of enveloped virions in large vesicles in the cytoplasm
of infected Vero cells and failure of release of these virions into the
extracellular space. No obvious alterations in maturation of
glycoproteins expressed in Vero cells infected with the
PrV-UL20 mutant were observed, but not all glycoproteins
were investigated (10). Here we show that the absence of the
UL20 protein specifically affects processing of gK, which indicates
there is an intimate connection between these two
multiply-membrane-spanning virion proteins.
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MATERIALS AND METHODS |
Viruses and cells.
Virus mutants were derived from wild-type
PrV strain Kaplan (PrV-Ka) (19). PrV-1112 carries a
-galactosidase expression cassette in the gG locus and exhibits
growth properties similar to those of PrV-Ka (28). Mutant
viruses PrV-UL20 (10), and
PrV-UL3.5, (9) as well as rescuant PrV-UL20R
(10), have been described. Construction of PrV-gK (see
Fig. 1C) has been described before (25). Viruses were grown
on rabbit (RK13) or African green monkey (Vero) kidney cells for plaque
assays, one-step growth kinetics, Western blot analysis, and
immunofluorescence. Porcine kidney cells (PSEK) were used for virus
propagation followed by virion purification. Cells were propagated in
Eagle's minimum essential medium supplemented with 5 or 10% (RK13)
fetal calf serum. Cotransfections were performed by calcium phosphate
coprecipitation (11). RK13 cells were transfected with
SuperFect (Qiagen, Hilden, Germany).
Construction of PrV-
gKw.
For the construction of
PrV-gKw, a gK deletion mutant lacking most of the UL53 gene, a
4.2-kb AatII subfragment of the BamHI 5' fragment
was inserted into pUC19, cleaved with NruI (Fig. 1B), a
singular restriction site within this subfragment, and digested with
exonuclease Bal31 for bidirectional deletion of the UL53 ORF. The resulting plasmid, pUC19/gK/Bal31, carries a large deletion from codon 48 to codon 275 of the gK ORF (corresponding to nucleotides [nt] 4058 to 4743 of GenBank accession no. X87246) (Fig. 1D), as
verified by sequencing. After cotransfection with genomic DNA of
PrV-gK, recombinant viruses were screened for a white plaque phenotype. One single plaque isolate, designated as PrV-gKw, was
further characterized. The genotype was verified by restriction analysis and Southern blotting (data not shown).
Construction of cell lines.
For the construction of
gK-expressing cell lines, the complete UL53 gene (nt 3918 to 4856)
(3) and the UL53 gene from a second possible start codon (nt
3963 to 4856) (3) were amplified by PCR with Pfu
polymerase (Promega, Mannheim, Germany). The forward primers, which in
their 5' extensions create a novel HindIII restriction site (underlined) were as follows: gK-1
(5'-ATAAGCTTCATGCTCCTCGGCGGGCGCC-3'; nt 3916 to
3936) and gK-2 (5'-AGAAGCTTGGTGATGGGCGCGTACGCCGG-3'; nt 3959 to 3979). The reverse primer, which adds an
XbaI restriction site at the 3' end of the amplified
products (underlined), was gK-3
(5'-AGTCTAGACGTCCCCGCGCCGACCTTCATCC-3'; nt 4873 to 4851). The PCR product gK1-3 was inserted into
HindIII- and XbaI-cleaved vector pcDNA3
(InVitroGen, Leek, The Netherlands), and the gK2-3 product was inserted
into pRc/CMV (InVitroGen). The correct sequences of gK1-3 and gK2-3
were confirmed by direct sequencing with the T7 DNA sequencing kit
(U.S. Biochemicals, Cleveland, Ohio). Plasmids were used for
transfection of RK13 cells by SuperFect (Qiagen, Hilden, Germany).
Transfectants were selected with 500 µg of Geneticin (Life
Technologies, Eggenstein, Germany) per ml and tested for gK expression
by indirect immunofluorescence (data not shown), Western blotting, and
their ability to complement PrV gK mutants in trans. One
cell clone each was selected and designated RK13-gK1-3 (complete gK
ORF) and RK13-gK2-3 (gK from the second possible translation start).
For transient transfection of RK13-gK1-3 cells, a UL20 expression
plasmid, designated pcDNA3-UL20, was constructed. To this end, the UL20
gene was amplified by PCR with a forward primer, which creates an
EcoRI restriction site at the 5' end of the amplified product (underlined)
5'-CACAGAATTCGCGGCGCGGGGATGGAGGAC-3' (nt 6673 to
6692 of GenBank accession no. L00676) (21, 23); and a
reverse primer, which adds an XhoI restriction site at the 3' end of the amplified product (underlined),
5'-CACACTCGAGGTCGCTGGGGAGCAGGGGGG-3' (nt 7219 to
7200). After restriction enzyme cleavage, the PCR product was cloned
into EcoRI- and XhoI-cleaved vector pcDNA3.
Plaque assay.
Plaque formation was analyzed after titration
of virus mutants on various cell lines 2 days after infection under a
methylcellulose overlay. Thereafter, cells were fixed and stained with
X-Gal (5-bromo-4-chloro-3-indolyl--D-galactopyranoside) as described elsewhere (25). Although PrV-gKw does not
express -galactosidase, the same procedure was used to document
unstained plaques or foci of infected cells.
Preparation of MAbs against gK.
A bacterial fusion protein,
pGEX-Bst XI/XhoI, encompassing codons 64 to 196 of the UL53 ORF fused to the glutathione S-transferase gene
(25), was used for preparation of monoclonal antibodies (MAbs). Twelve-week-old mice were immunized intramuscularly with 100 µg of purified fusion protein mixed with complete Freund's adjuvant
(Sigma, Deisenhofen, Germany). Subsequent immunizations were made with
incomplete Freund's adjuvant after 6 weeks and, thereafter, repeated
seven times in 4-week intervals. Four days prior to fusion, a booster
immunization was applied. Hybridoma supernatants were differentially
screened by Western blotting with purified virion preparations of
PrV-Ka and PrV-gK. Indirect immunofluorescence was performed with
PrV-Ka-infected cells. The resulting MAb D4-1 was selected for Western
blotting; MAb b7-b6 was selected for indirect immunofluorescence (data
not shown).
Western blot analysis of cell lysates and virions.
Cell
lysates were harvested 24 or 48 h after infection or transfection.
After centrifugation at 14,000 rpm for 1 min in an Eppendorf
centrifuge, cells were washed twice with phosphate-buffered saline
(PBS), resuspended in 100 µl of PBS, and mixed with the same volume
of sample buffer. Virions were purified as described previously
(24). Briefly, cells were infected and incubated until
complete CPE developed. Medium was removed and cells were lysed in PBS
by three freeze (
70°C) and thaw (37°C) cycles. Cellular material
was removed by low-speed centrifugation, and the resulting supernatant
was combined with the virus-containing medium. Virions were then
purified by sucrose gradient centrifugation. Twenty microliters of cell
lysate or 10 µg of purified virions was separated by sodium dodecyl
sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) (27),
electrotransferred onto polyvinylidene difluoride membrane (PVDF)
(Immobilon-P; Millipore, Eschborn, Germany) (37), and reacted for 1 h with monoclonal or polyclonal antibodies against PrV glycoproteins diluted in PBS as follows: b43-b5 (anti-gB), 1:1,000;
B16-c8 (anti-gC), 1:100; A9-b15 (anti-gE) 1:100 (26); D4-1
(anti-gK), 1:50 (this study); Vacc-gD 1:1,000 and glutathione S-transferase (GST)-gH 1:50,000 (24); GST-gI
1:50,000 (4), GST-gL 1:1,000 (22), anti-gM
peptide serum 1:5,000 (6), and Baculo-gN 1:500
(18). After incubation with peroxidase-conjugated secondary
antibody (Dianova, Hamburg, Germany), bound antibody was visualized by
enhanced chemiluminescence (ECL Western blot system; Amersham,
Braunschweig, Germany) and detected on X-ray film.
Glycosidase digestions.
Deglycosylation studies were
performed as described elsewhere (25).
Tunicamycin treatment.
To inhibit N glycosylation,
tunicamycin (Sigma, Deisenhofen, Germany) at a concentration of 20 µg
per ml was added during infection of RK13 cells at a multiplicity of
infection (MOI) of 1. After 24 h at 37°C, infected cells were
harvested, and cell lysates were analyzed by Western blotting.
One-step growth analysis.
For analysis of growth behavior,
RK13 and RK13-gK1-3 cells were infected with PrV-Ka, PrV-gK, and
PrV-gKw at an MOI of 5. After 1 h at 4°C, the inoculum was
removed, prewarmed medium was added, and virus was allowed to penetrate
for 1 h at 37°C. The remaining extracellular virus was
inactivated by low-pH treatment. Immediately thereafter and after 4, 8, 12, 24, and 34 h, supernatant and cells were harvested separately
and titrated. The cell pellet was treated by low pH to inactivate
cell-associated but extracellular infectious virus. Titers of extra-
and intracellular virus progeny were added, and average values and
standard deviations of two independent experiments were calculated.
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RESULTS |
Construction and phenotypic characterization of PrV gK
mutants.
Recently, a PrV gK mutant, PrV-gK, has been
characterized in which the UL53 ORF had been interrupted after codon
164 by insertion of a gG-lacZ expression cassette (Fig.
1C) (25). Since in this mutant
the expression of a truncated N-terminal gK fragment of 164 amino acids
was still possible, another mutant, PrV-gKw, was constructed by
bidirectional exonuclease digestion beginning at a single
NruI restriction site located in the middle of the UL53 gene
(Fig. 1B). This mutant carries a large deletion in the UL53 ORF,
starting after codon 47 and extending until codon 275 (Fig. 1D).
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FIG. 1.
Construction of PrV-gK mutants. (A) A schematic map of
the PrV genome with the BamHI restriction fragment map is
depicted. The PrV genome consists of a unique long region
(UL) and a unique short region (US); the latter
is flanked by inverted repeats (IR, internal repeat; TR, terminal
repeat). (B) Enlargement of the BamHI 5' region. The
locations of the identified ORFs, with transcriptional orientation
indicated by arrows, are shown (R, region of reiterated sequences), and
relevant restriction sites for cloning are indicated (3).
BamHI 5' genome organization for the UL52, UL53, and UL54
genes of the insertion mutant PrV-gK (C) (25) and gK
deletion mutant PrV-gKw (D). Shaded slashes in panels C and D
indicate the figure is not drawn to scale.
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To analyze the growth properties of the gK mutants, plaque assays on
normal RK13 and gK-expressing cells were performed. Two
days after
infection, plaques or foci of infected cells were analyzed.
As shown in
Fig.
2, PrV-1112 forms similar plaques on
all cell
lines tested. In contrast, the gK-negative mutants were unable
to form plaques on parental RK13 cells, but were capable of plaque
formation on RK13-gK1-3 cells which constitutively express gK
from the
first methionine. RK13-gK2-3 cells which express gK from
the second
in-frame methionine did not complement plaque formation
in any gK
mutant. These data confirm the important role of gK
in plaque formation
of PrV and indicate that functional gK is
expressed only from the first
methionine in the UL53 ORF.
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FIG. 2.
Plaque formation of PrV-gK mutants under plaque assay
conditions. Normal RK13 cells and constitutively gK-expressing
RK13-gK1-3 and RK13-gK2-3 cells were infected with PrV-1112, PrV-gK,
and PrV-gKw for 2 days. The cells were then fixed, stained, and
photographed. Bar, 1 mm.
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One-step growth kinetics of PrV gK mutants.
To further
investigate replication of PrV gK mutants, one-step growth kinetics
were assayed on noncomplementing RK13 (Fig. 3A) and complementing RK13-gK1-3 (Fig.
3B) cells after infection with PrV-Ka, PrV-gK, and PrV-gKw at an
MOI of 5. Virus progeny was titrated on complementing cells, and
average values as well as standard deviations of two independent
experiments were calculated. The interruption or deletion of the UL53
ORF resulted in a significant growth defect on RK13 cells at all times
postinfection compared to PrV-Ka. Final viral titers of PrV-gK and
PrV-gKw were reduced by about 50-fold. On complementing RK13-gK1-3
cells, replication of PrV-gK and PrVgKw was comparable to that of
PrV-Ka and resulted in nearly identical final titers.
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FIG. 3.
One-step-growth kinetics. RK13 (A) and RK13-gK1-3 (B)
cells were infected at an MOI of 5 with PrV-Ka, PrV-gK, and
PrV-gKw. After the indicated times, supernatant and cells were
harvested and titrated on complementing cells. The calculated virus
titers of supernatant and cells were added. The mean values with
standard deviations of two independent experiments are shown.
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Analysis of constitutively gK-expressing cell lines.
Two
constitutively gK-expressing cell lines were constructed. RK13-gK1-3
cells expressed the complete gK, whereas RK13-gK2-3 cells were only
able to express a gK from a second possible translational start codon.
To investigate the expression products in detail, lysates of RK13-gK1-3
and RK13-gK2-3 cells infected with PrV-Ka, PrV-gK, and PrV-gKw or
mock-infected cells were separated by PAGE under reducing conditions,
blotted onto PVDF membrane, and probed with MAb D4-1 directed against
PrV gK. As shown in Fig. 4, in purified
virion preparations of PrV-Ka, MAb D4-1 recognized the glycosylated ca.
36-kDa mature gK, which appeared as a broad band indicative of
glycosylated proteins (Fig. 4, lane 1), as well as a 34-kDa form after
treatment with endo--N-acetylglucosaminidase H (endo H)
(Fig. 4, lane 2) and a 32-kDa form after PNGase F digest (Fig. 4, lane
3).
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FIG. 4.
Western blot analysis of constitutively gK-expressing
cell lines. Proteins were separated by 10% PAGE, blotted onto PVDF
membrane, and incubated with a MAb against gK ( gK). Samples were
purified PrV virions (lane 1) after incubation with endo H (lane 2) or
PNGase F (lane 3); lysates of noninfected RK13 cells (lane 4) or RK13
cells after infection with PrV-Ka (lane 5); lysate of RK13-gK1-3 cells
(lane 6) infected with PrV-Ka (lane 7), PrV-gK (lane 8), or
PrV-gKw (lane 9); or cell lysate of RK13-gK2-3 cells (lane 10)
infected with PrV-Ka (lane 11), PrV-gK (lane 12), or PrV-gKw
(lane 13). The locations of molecular mass markers are indicated on the
left.
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Surprisingly, expressed proteins detected by the anti-gK MAb in
RK13-gK1-3 and RK13-gK2-3 cells were different from gK found
in
purified virions. As shown in Fig.
4, lane 6, a major protein
with a
molecular mass of around 34 kDa and a minor expression
product of 28 kDa were detected in RK13-gK1-3 cells, whereas RK13-gK2-3
cells
expressed a protein of 33 kDa and two smaller products of
27 and 28 kDa
(Fig.
4, lane 10). Notably, these protein bands
all lacked the
"smeary" appearance found in mature gK. Interestingly,
after
infection of RK13-gK1-3 cells with wild-type PrV (Fig.
4,
lane 7) or
any of the gK mutants (Fig.
4, lanes 8 and 9), a broad
protein band of
ca. 36 kDa was recognized as the main protein
which appeared comparable
to gK detected in PrV-Ka-infected RK13
cells (Fig.
4, lane 5) and
purified PrV-Ka virions (Fig.
4, lane
1). In contrast to RK13-gK1-3
cells, the glycosylated ca. 36-kDa
form of gK could only be recognized
in RK13-gK2-3 cells infected
with PrV-Ka (Fig.
4, lane 11), but not
after infection with any
of the gK mutants (Fig.
4, lanes 12 and 13).
The smaller protein
species present in these cell lines may represent
precursor forms,
since a gK precursor protein with an apparent
molecular mass of
ca. 28 kDa has been identified in earlier in vitro
translation
studies (J. Baumeister et al., unpublished observations).
The
alteration in the gK pattern after infection of RK13-gK1-3 cells
may indicate that gK is not completely processed in these cells
when
expressed alone. Indirect immunofluorescence analysis of
both cell
lines could not clarify whether gK was expressed on
the cell surface,
since the MAb recognized gK only in permeabilized
cells. Here a
diffuse, equally distributed cytoplasmic fluorescence
was detected for
both cell lines (not
shown).
gK is a structural component of virions of gK mutants grown on
RK13-gK1-3 cells, but not on RK13-gK2-3 cells.
To test for
incorporation of gK expressed from the transgenic cell lines into
virions, Western blot analyses of purified virions were performed.
RK13, RK13-gK1-3, and RK13-gK2-3 cells were infected with PrV-Ka,
PrV-gK, and PrV-gKw at an MOI of 1, cells and supernatant were
harvested 2 days after infection, and virions were purified. Proteins
were separated by SDS-PAGE, blotted, and incubated with anti-gK MAb
D4-1 (Fig. 5A). For control, the blot was
then stripped and reprobed with a polyclonal anti-gH serum (Fig. 5B).
The ca. 36-kDa mature gK was recognized in PrV-Ka virions grown on
RK13, RK13-gK1-3, and RK13-gK2-3 cells (Fig. 5A, lanes 1). A protein with similar electrophoretic mobility was also detected in all virion
preparations of gK mutants which had been propagated on RK13-gK1-3
cells (Fig. 5A, middle panel, lanes 2 and 3), whereas in virions from
gK mutants propagated on RK13-gK2-3 cells, no gK was recognized (Fig.
5A, right panel, lanes 2 and 3). In contrast, the 95-kDa gH was
detected similarly in all virion preparations independent of the cell
line used for propagation. These results show that the protein
expressed from a second in-frame methionine in the UL53 ORF is not
incorporated into virions. Therefore, the first translation start codon
appears to be used for correct translation of PrV gK.
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FIG. 5.
Identification of gK in virions propagated on different
gK-expressing cell lines. Purified virions of PrV-Ka (lanes 1),
PrV-gK (lanes 2), and PrV-gKw (lanes 3) were isolated from RK13,
RK13-gK1-3, and RK13-gK2-3 cells and analyzed by Western blotting after
separation in a 10% polyacrylamide gel. The blot was incubated with a
MAb against gK (A [gK]) then stripped and probed with a
gH-specific rabbit serum [gH]). The locations of molecular mass
markers are indicated on the left.
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Identification of another viral protein that is involved in the
correct processing of gK.
Obviously, the gK protein as expressed
from RK13-gK1-3 cells migrates with an electrophoretic mobility which
is different from that of mature gK as detected after infection. To
check whether another viral protein is required for efficient
glycosylation of gK, cell lysates and purified virion preparations of a
multitude of PrV glycoprotein mutants available in our laboratory
(mutants lacking gB, gC, gD, gE, gG, gH, gI, gL, gM, or gN, as well as several double and triple mutants) were tested for expression of gK by
Western blotting (not shown). The blots clearly demonstrated that the
mature 36-kDa form of gK was expressed by all virus mutants tested.
These findings indicated that other glycoproteins of PrV seemed not to
be involved in the processing of gK. Furthermore, cell lysates of two
virus mutants with defects in virus egress, PrV-UL20 and
PrV-UL3.5, were analyzed. As shown in Fig.
6, lane 4, the gK signal detected in
PrV-UL20-infected cells was smaller than and not as
diffuse as the signal normally observed for gK. In
PrV-UL3.5-infected cells (Fig. 6, lane 5) gK was
comparable to the gK present in purified PrV-Ka virions (Fig. 6, lane
1) and infected cell lysates (Fig. 6, lane 3). This indicates that the
UL20 gene product of PrV may be involved in the processing of gK.
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FIG. 6.
Expression of gK in two different PrV mutants with
defects in the virus egress pathway. Noninfected RK13 cells (lane 2) or
RK13 cells infected with PrV-Ka (lane 3), PrV-UL20 (lane
4), or PrV-UL3.5 (lane 5) were harvested 24 h after
infection and separated by 10% PAGE. Purified PrV-Ka virions (lane 1)
were used as a positive control. Expression of gK was detected by the
anti-gK MAb (gK). The locations of molecular mass markers are
indicated on the left.
|
|
To analyze whether expression and/or modification of other
glycoproteins is altered in PrV-UL20
-infected cells, all
known structural glycoproteins of PrV were
analyzed in
PrV-UL20
-infected RK13 cell lysates by Western blotting
with a panel of
monoclonal and polyclonal antibodies (Fig.
7). The experiment
clearly showed that
the amounts and apparent molecular weights
of the other glycoproteins
expressed in PrV-UL20
infected cells (Fig.
7, lanes 2)
were identical to those of proteins
of PrV-Ka-infected cells (Fig.
7,
lanes 1). Only the appearance
of gK was altered in
PrV-UL20
-infected cells. Moreover, the incompletely
processed form of
gK was also detectable in purified
PrV-UL20
virions (Fig.
8,
lane 2), whereas the corresponding UL20 rescue
mutant showed a mature
gK (Fig.
8, lane 3). gB and gC, used as
controls, were unaltered (Fig.
8).
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|
FIG. 7.
Analysis of glycoproteins in
PrV-UL20-infected cells. Lysates of RK13 cells infected
with PrV-Ka (lanes 1) and the PrV-UL20 mutant (lanes 2)
were separated by 10% (A) or 12% (B) PAGE and blotted. Thereafter,
the membrane was incubated with monoclonal or polyclonal antibodies
() against PrV glycoproteins as indicated at the bottom. The
locations of molecular mass markers are indicated to the left of each
panel.
|
|
View larger version (40K):
[in this window]
[in a new window]
|
FIG. 8.
Incorporation of incompletely processed gK into
PrV-UL20 virions. Purified PrV-Ka (lanes 1),
PrV-UL20 (lanes 2), and PrV-UL20R (lanes 3) virions were
lysed and analyzed by Western blotting after separation in a 10%
polyacrylamide gel. The blot was incubated with MAbs against gK
(gK), gB (gB), or gC (gC).
|
|
To exclude the possibility that the smaller form of gK expressed in
PrV-UL20
-infected cells is due to differences in the
protein backbone,
infected cell lysates were analyzed by Western
blotting before
and after tunicamycin treatment. After inhibition of N
glycosylation,
the same gK-specific signal was recognized in the cell
lysate
of PrV-Ka- and PrV-UL20
-infected cells (data not
shown).
Coexpression with UL20 partially restores gK processing.
To
demonstrate that the UL20 gene product is required for processing of
gK, RK13-gK1-3 cells were transfected with pcDNA3-UL20 and analyzed by
Western blotting 24 or 48 h after transfection. As shown in Fig.
9A, an increase in the apparent molecular
mass of cellularly expressed gK (Fig. 9, lane 2) indicative of
processing was first observed 24 h after transfection (Fig. 9,
lane 3), which grew more pronounced 48 h after transfection (Fig.
9, lane 4). Thus, coexpression of UL20 at least partially restored
processing of gK. For comparison, mature gK present in purified virions
is shown in Fig. 9A, lane 1. As controls, lysates of RK13-gK1-3 cells (Fig. 9A, lanes 5 and 6) or RK13 cells (Fig. 9A, lanes 7 and 8) infected with PrV-Ka (Fig. 9A, lanes 5 and 7) or PrV-UL20
(Fig. 9A, lanes 6 and 8) were probed with the anti-gK MAb. After PNGase
F digestion (Fig. 9B, lanes 1 to 8), the molecular masses of gK were
identical at 32 kDa in all samples. This indicates that the observed
processing of gK in the presence of UL20 is effected by N-linked
glycosylation. When gK-expressing RK13-gK1-3 cells were first
transfected with the UL20 expression plasmid and then infected with
UL20-negative PrV, fully processed gK was detected (data not shown).
View larger version (54K):
[in this window]
[in a new window]
|
FIG. 9.
Western blot analysis of gK expressed in RK13-gK1-3
cells after transient expression of UL20. Proteins of purified PrV-Ka
virions (lane 1), lysate of RK13-gK1-3 cells (lane 2), and RK13gK1-3
cells transfected with pcDNA3-UL20 24 h (lane 3) or 48 h
(lane 4) after transfection were separated in an SDS-10%
polyacrylamide gel and probed with the anti-gK MAb (gK). As
controls, lysates of RK13-gK1-3 cells infected with PrV-Ka (lane 5) or
PrV-UL20 (lane 6) and of RK13 cells infected with PrV-Ka
(lane 7) or PrV-UL20 (lane 8) after incubation with the
anti-gK MAb are included. (A) Samples without PNGase F digestion. (B)
Samples after PNGase F digestion. In panel B, lane is an
undigested control of PrV virion proteins. The locations of molecular
mass markers are indicated on the left.
|
|
| |
DISCUSSION |
In this report, we show a specific effect on maturation of gK by
inactivation of the UL20 gene. Both UL20 and gK play a role in virus
egress from infected cells. Whereas in cells infected with PrV gK
mutants, virion morphogenesis appears to proceed normally until release
of virions into the extracellular space (25), in cells
infected with PrV-UL20, enveloped virions were shown to
accumulate in huge vacuoles and are only inefficiently released
(10). Thus, the UL20 protein seems to be functionally
required before gK function is needed. So far, the nature of the
interplay between UL20 and gK is unclear. Both are membrane proteins
(12, 31, 38). HSV-1 gK has been shown to span the membrane
three times, and the UL20 protein also contains hydrophobic domains of
sufficient length to traverse the lipid bilayer up to four times. Thus,
both seem to be intimately associated with membranes. Since we do not
yet have serologic reagents to detect the PrV UL20 protein, it is
unclear whether the observed dependence of gK processing on the UL20
protein is associated with the formation of a physical complex between
the two polypeptides. However, it is clear from our results that the effect on glycoprotein maturation by the UL20 protein is specific for
gK. None of the other known viral structural glycoproteins seems to be
affected. Surprisingly, the incompletely processed form of gK is
incorporated into virions in the absence of the UL20 protein,
indicating (i) that proper processing of gK is not required for virion
incorporation and (ii) that the UL20 protein is required for
maturation, but not for virion localization of gK. A possible
explanation for the effect on maturation is that by interaction with
gK, the UL20 protein mediates retention of a conformation of gK which
renders it amenable for processing. In the absence of the UL20 protein,
gK could assume a different conformation which does not allow
processing to occur. Using our MAbs, we are currently trying to analyze
this phenomenon.
Our data also show that functional gK is only expressed from the first
in-frame methionine present in the UL53 ORF (3). Cells
constitutively expressing gK from this start codon complement insertion
(PrV-gK) and deletion (PrV-gKw) mutants with regard to plaque
size and one-step growth, and the cellularly expressed gK is properly
processed and incorporated into virions. In contrast, from the second
in-frame methionine, a gK form is expressed which, although migrating
in SDS-PAGE similarly to gK expressed from the first methionine, is not
properly processed and is not incorporated into virions. Also, these
cells do not complement plaque formation of either of the gK mutants.
Studies of PrV gK were greatly facilitated with the isolation of two
MAbs which recognize gK. These are the first MAbs described which are
specific for herpesvirus gK proteins. Our analyses confirm that mature
ca. 36-kDa virion gK contains ca. 2 kDa of endo H-sensitive carbohydrates and an additional 2 kDa of PNGase F-sensitive N-linked glycans. Interestingly, in RK13-gK1-3 cells, a 34-kDa species which
comigrates with the endo H-digested virion gK is expressed, which is
then apparently correctly processed after superinfection by wild-type
PrV and either of the gK mutants and is incorporated into virions. An
only slightly smaller protein of 33 kDa is present in RK13-gK2-3 cells;
however, it is not processed after superinfection with gK-deletion
mutants and is not present in virions propagated on these cells. Thus,
the product expressed from the second in-frame methionine within UL53
is detected by the MAb in cell lysates, but is not functional. In these
cells, a prominent, second 28-kDa form of gK is recognized by the MAb
which may represent a stable breakdown product of the 33-kDa gK.
Whereas the inhibition of gK processing in cells infected with
PrV-UL20 indicated that the UL20 protein is necessary for
gK maturation, it did not exclude an indirect effect. However,
transfection of RK13-gK1-3 cells with a UL20 expression plasmid at
least partially restored gK processing, which shows a direct effect of
UL20 on gK. The fact that gK processing appeared to be restored only
partially may be explained by the transfection efficiency with the UL20 expression plasmid, which never reaches 100% of gK-expressing cells,
and the timing of the expression of the two proteins which is certainly
different in the transfected cell line from that in virus-infected
cells. On the other hand, it cannot be excluded that yet another viral
protein is required for complete processing of gK.
HSV-1 UL20 has been implicated in compensation for disruption of the
Golgi apparatus late after infection, and UL20-deletion mutants of
HSV-1 have been shown to exhibit defects in the processing of gC and gD
(1). In PrV, except for gK, the processing of none of the
other known structural viral glycoproteins appears to be affected,
which cannot be explained by a more general disruption of the protein
export pathway. In contrast, the specific effect of the UL20 deletion
on gK indicates that both intimately cooperate.
Electron microscopical analyses of our first gK mutant, PrV-gK
(25), indicated that, in the absence of gK, virions are released from infected cells, but immediately fuse with the cell they
left. Thus, gK was postulated to play a role in interference. We tried
to test this hypothesis by establishing the gK-expressing cell lines
that are described in this report. However, these cells did not show
any interference, which, with hindsight, may now be explained by the
fact that these cells do not express mature gK in the absence of the
UL20 protein. Therefore, we are currently trying to construct cells
coexpressing gK and UL20, which are more likely to express functional gK.
Although in both HSV-1 and PrV, the UL20 and gK proteins are involved
in virion maturation and egress, there are differences in the
phenotypes displayed by the respective mutants. In HSV-1, deletion of
UL20 resulted in accumulation of enveloped virions in the perinuclear
space (2) and disruption of the Golgi apparatus with
concomitant alteration of glycoprotein maturation (1), whereas in the absence of gK, enveloped virions accumulated in the
cytoplasm (16). In PrV, deletion of UL20 resulted in
accumulation of enveloped virions within intracytoplasmic vesicles
(10). In the absence of gK, virion morphogenesis appears to
proceed normally, but extracellular virions are found only rarely
(25). Most strikingly, in cells infected with gK-negative
PrV, numerous intracellular nucleocapsids were found close to the
plasma membrane, and fusion events were observed which might represent
entry stages of released virions. Since HSV-1 UL20 and gK-null mutants
exhibited different phenotypes on different cells, indicating partial
complementation by cellular factors (2, 16), we cannot
exclude that the differences in phenotypes between HSV-1 and PrV are,
at least partially, due to the difference in cell systems. However,
from our data, we deduce that UL20 function precedes gK function, which
would imply that a UL20-gK double mutant should exhibit essentially a
UL20 phenotype. Our future goal is to isolate and analyze this mutant after establishment of doubly expressing cells.
| |
ACKNOWLEDGMENTS |
This work was supported by the Deutsche Forschungsgemeinschaft
(Me 854/4-1) and the European Union (EEC-contract no. BMH4-CT97-2573).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Institute of
Molecular Biology, Friedrich-Loeffler-Institutes, Federal Research
Centre for Virus Diseases of Animals, D-17498 Insel Riems, Germany.
Phone: 49-38351-7102. Fax: 49-38351-7151. E-mail:
mettenleiter{at}rie.bfav.de.
| |
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Journal of Virology, June 2000, p. 5083-5090, Vol. 74, No. 11
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
