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Journal of Virology, January 1999, p. 417-426, Vol. 73, No. 1
0022-538X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
The Ability of Herpes Simplex Virus Type 1 Immediate-Early
Protein Vmw110 To Bind to a Ubiquitin-Specific Protease Contributes
to Its Roles in the Activation of Gene Expression and
Stimulation of Virus Replication
Roger D.
Everett,*
Michayla
Meredith,
and
Anne
Orr
MRC Virology Unit, Glasgow G11 5JR, Scotland,
United Kingdom
Received 22 June 1998/Accepted 8 October 1998
 |
ABSTRACT |
Herpes simplex virus type 1 immediate-early protein Vmw110
stimulates the onset of virus infection and is required for efficient reactivation from latency. In transfection assays, Vmw110 is a potent
activator of gene expression, but its mode of action has yet to be
determined. Previous work has shown that Vmw110 localizes to specific
intranuclear structures known as ND10, PML bodies, or PODs and causes
the disruption of these domains. The ability of Vmw110 to disrupt ND10
correlates with its biological activities in infected and
transfected cells. It has also been found that Vmw110 binds strongly
and specifically to a ubiquitin-specific protease known as HAUSP,
itself a component of a subset of ND10. In this study we have
investigated the role of HAUSP in Vmw110 activity; single amino acid
residues of Vmw110 required for the interaction were identified, and
the effects of mutation of these residues in infected and transfected
cells were then assayed. The results indicate that the ability to bind
to HAUSP contributes to the functional activities of Vmw110.
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INTRODUCTION |
Herpes simplex virus type 1 (HSV-1)
immediate-early (IE) protein Vmw110 (also known as ICP0) is an
important regulator of viral gene expression which augments expression
from transfected reporter genes and stimulates the onset of the viral
lytic cycle (reviewed in reference 9). Failure to
express functional Vmw110 decreases the probability that the virus will
enter the lytic cycle after infection at low multiplicity of infection
in cell culture (2, 8, 34). The genomes which fail to
initiate lytic gene expression attain a quiescent state with
similarities to latency, and provision of exogenous Vmw110 leads to
their reactivation (18, 33). Consistent with the results
obtained with cultured cells, Vmw110-deficient viruses reactivate
poorly in mouse latency models (3, 24), and these data have
led to the idea that Vmw110 has a role in determining whether the virus
enters the lytic cycle or establishes a latent infection.
The mechanisms that underlie the functions of Vmw110 have not
been clearly defined, although a recent study of
Vmw110-activated gene expression ruled out posttranscriptional
regulation (20). Mutagenesis experiments have identified
several functional regions of Vmw110, including a characteristic zinc
binding domain called a RING finger that lies in the N-terminal third
of the protein, a nuclear localization signal, and sequences in the
C-terminal 180 residues (reviewed in reference 9).
Recent studies have explored the intermolecular interactions of Vmw110,
and several candidate functional interactions have been identified. Two
studies have suggested that Vmw110 might interact with Vmw175 (ICP4), the major transcriptional regulator expressed by HSV-1, although direct
proof that such an interaction occurs in infected cells remains to be
established (31, 36). Other studies have concentrated on the
possible interactions between Vmw110 and cellular proteins and
structures. It is now firmly established that at the earliest stages of
infection Vmw110 migrates to specific nuclear structures termed ND10,
PODs, or PML nuclear bodies, and in consequence the ND10 are disrupted
(11, 26, 27). The ability of Vmw110 to interact normally
with and disrupt ND10 appears to be functionally significant, since
mutations that affect the biological activities of Vmw110 also affect
its interactions with ND10 (11, 27). The initial observation
that ND10 constitute a preferred site for the localization of parental
viral genomes and the subsequent development of replication
compartments (19, 28) has now been confirmed by other
laboratories (25, 35).
At the molecular level, Vmw110 interactions with the translation factor
elongation factor (EF) 1
(21) and cyclin D3 have been
observed in vitro and in the yeast two-hybrid system (22). The interaction that we have concentrated on in this laboratory is that
between sequences in the C-terminal region of Vmw110 and a novel
ubiquitin-specific protease named HAUSP (13, 29, 30). The binding of Vmw110 to HAUSP is both strong and specific in vitro and is readily observable by coimmune precipitation of the complex from infected cell extracts. An initial observation which suggested that the Vmw110-HAUSP interaction was functionally
significant was the localization of the latter in a subset of ND10 in
uninfected cells (13). Ubiquitin-specific protease (USP)
enzymes are likely to have a role in the control of protein stability
since they cleave ubiquitin adducts from substrate proteins, thereby
protecting the substrate from proteasome-mediated degradation. In
principle, Vmw110 could be inhibiting, activating or redirecting the
natural enzymatic activity of HAUSP, and there are several examples of regulation of gene expression mediated by modulation of the stability of components of regulatory pathways (see reference
13 for further discussion). The association between
Vmw110 and HAUSP has recently become particularly intriguing because of
the finding that a major biochemical function of Vmw110 is indeed the
control of the stability of a number of cellular proteins. For example,
at early times during infection Vmw110 induces the degradation of
certain isoforms of the major ND10 proteins PML (14) and
sp100 (15), events which correlate with the disruption of
ND10 (14). The induced degradation can be inhibited by
inactivation of the ubiquitin-proteasome pathway (14), and
under these conditions infection becomes stalled at the IE stage in a
way that mirrors the requirement for Vmw110 (17). However,
the ND10 proteins are not the sole targets for Vmw110-induced
proteolysis since the inner centromere protein CENP-C (16)
and the catalytic subunit of DNA-PK (23, 32) are also lost
from the cell in a Vmw110-dependent manner.
The fact that Vmw110 binds to a ubiquitin-specific protease and induces
the degradation of certain specific proteins is a compelling indication
that the interaction with HAUSP is functionally significant. However,
analysis of the importance of the interaction has hitherto been
complicated by the complexity of the C-terminal region of Vmw110. For
example, although the phenotypes of Vmw110 deletion mutants with
lesions in the HAUSP binding region are consistent with a role for the
interaction in virus infection (7, 30), the available
deletions encroach closely on sequences required for migration of
Vmw110 to ND10 and for self-multimerization (reference
30 and references therein). We wished to analyze the
functional requirements for HAUSP binding by Vmw110 as rigorously as possible by conducting a fine-structure analysis of the
Vmw110 sequences required. A number of mutants with single or
double amino acid substitutions of Vmw110 which reduced the interaction to background levels in vitro were identified. The ability of Vmw110 to
activate gene expression in transfection assays was significantly
diminished by these mutations, and virus mutants carrying
these substitutions grew poorly in tissue culture. We conclude that the
ability of Vmw110 to bind to HAUSP makes a significant contribution to
the ability of Vmw110 to activate gene expression and stimulate virus
growth in cultured cells.
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MATERIALS AND METHODS |
Viruses and cells.
HSV-1 strain 17+ was the wild-type strain
used in these studies. Virus dl1403, from which the majority
of the Vmw110 coding region has been deleted, was derived from strain
17+ (34). The FXE, E52X, D12, and D14 viruses with defined
deletions in Vmw110 have been described previously (8, 30).
All viruses were propagated and titrated in baby hamster kidney (BHK)
cells grown in Glasgow modified Eagle's medium containing 100 U of
penicillin/ml and 100 µg of streptomycin/ml and supplemented with
10% newborn calf serum and 10% tryptose phosphate broth. HeLa cells
were grown in Dulbecco's modified Eagle's medium (DMEM) supplemented
with 2.5% fetal calf serum, 2.5% newborn calf serum (NBCS), and
antibiotics as described above. HEp-2 cells were grown in DMEM
containing 10% fetal calf serum and antibiotics, and Cos7 cells were
grown in DMEM containing 10% NBCS and antibiotics.
Construction of viruses with lesions in Vmw110.
The viruses
with defined lesions in Vmw110 which were generated for this study
included the truncation and deletion mutants E58X, A8X, and A78 and the
substitution mutants M1, M2, and M4 (see below and Table 2 for
details). Infectious dl1403 DNA was cotransfected with
linearized DNA of plasmids carrying the relevant mutations (see below).
The progeny plaques were screened by Southern blotting and plaque
purified three times before preparation of stocks, all as described
previously (8). The presence of the mutations was confirmed
by restriction enzyme analysis and Southern blotting of viral DNA
propagated from the final stocks (data not shown).
Plasmids. (i) GST fusion protein plasmids.
Glutathione
S-transferase (GST) fusion proteins were expressed from
plasmids derived from the vector pGEX2TN3; the C-terminal region of Vmw110 (residues 594 through 775) was expressed as a GST
fusion protein from plasmid pGEXE52 (29). Truncation
mutant derivatives of pGEXE52 were constructed as follows. Plasmids
pGEXE4 and pGEXE9 contain the EcoRI-SalI coding
region fragments of plasmids p110E4 and p110E9 (6) in place
of the EcoRI-SalI fragment of pGEXE52, thus
fusing residues 615 through 775 and 618 through 775 of Vmw110,
respectively, to GST. In these cases a derivative of the pGEX2TN3
vector was used to maintain the reading frame. The integrity of the
junction region was confirmed by DNA sequencing. Plasmids pGEXE52PmlI,
pGEXE52RsaI, and pGEXE52AvaI are 3' truncation derivatives of pGEXE52
which contain Vmw110 sequences from codon 594 in pGEXE52 to eponymous
restriction sites located after codons 713, 680, and 646, respectively.
They were constructed by cloning strategies incorporating multiple
fragments of pGEXE52, and in each case the stop codons are located in
vector sequences immediately downstream of the relevant restriction
site. Plasmids pGEXE23X and pGEXE58X have stop codon oligonucleotides
inserted into restriction sites located after codons 638 and 633, respectively. The stop codon linkers, which each contain an
XbaI site, were initially inserted into the EcoRI
sites in the insertion mutant plasmids p110E23 and p110E58
(6) to give plasmids p110E23X and p110E58X. Primers
overlapping codon 594 and the SalI site at the 3' end of the
Vmw110 coding region were used in PCRs with the derivative plasmids.
The 5' primer was designed with additional sequences containing an
EcoRI site so as to produce exactly the same sequence at the
5' end of the fragment as that present at the EcoRI site linking GST to Vmw110 sequences in pGEXE52. In this way, cleavage of
the PCR product with EcoRI and SalI produced a
fragment which could be used to replace the equivalent fragment
of pGEXE52, thereby creating plasmids pGEXE23X and pGEXE58X. The
details for these plasmids are summarized in Table 1. The
substitution-carrying mutant plasmids of the pGEXM series were
transferred from the intermediate p110M series plasmids (see below) by
the same PCR protocol as that used to create plasmids pGEXE23X and
pGEXE58X. Expression of the expected fusion proteins was confirmed by
Coomassie staining and Western blotting with monoclonal antibodies
(MAbs) 10503 and 10810, which recognize epitopes in the regions
downstream of position 633 and between residues 594 and 633, respectively (10).
(ii) Plasmids expressing Vmw110 and mutant derivatives in
eukaryotic cells.
Plasmid pCI110 was used to express Vmw110; this
contains the NcoI-HpaI IE-1 fragment containing
the Vmw110 coding region and IE-1 3' processing signals from plasmid
p111 (5) inserted downstream of the human cytomegalovirus
(HCMV) promoter-enhancer in vector pCIneo (Promega). Restriction
fragments containing the various mutations in the Vmw110 coding region
were excised from plasmid p110E58X, plasmids of the p110M series (see
below), and plasmids of the previously published p110 series
(6), and the mutant fragments were then used to replace the
corresponding wild-type fragment in pCI110.
Construction of amino acid substitution mutants.
The
MluI-SalI fragment of p111, containing Vmw110
residues 519 through 768, was inserted into M13 mp19, and uridine-rich
single-stranded template DNA was isolated from infected CJ236
Escherichia coli (ung dut mutant) in the presence
of 100 µg of uridine/ml. Three mutagenesis primers which contained
alterations in codons 621 and 622 were synthesized so as to produce a
novel FspI site without changing the coding potential. This
site was used to monitor transfer of mutagenized fragments. In
addition, the three primers were synthesized so as to allow alterations
(singly or in both) of the members of the codon pairs 619 and 620, 623 and 624, and 626 and 627 (for details, see Fig. 2). The primers were
used to generate double-stranded forms of the template M13 DNA and
transfected into the E. coli strain TG1, which detects and
preferentially degrades the uracil-containing template strand. Progeny
plaques were picked and screened for the presence of mutations by DNA sequencing. Replicative-form DNA from clones with desired mutations was
prepared, and their AatII-BstEII fragments
(containing Vmw110 codons 553 through 712) were excised and exchanged
for the corresponding fragment in plasmid p111 to generate plasmids of
the p110M series. Subsequently the mutant fragments were moved into the
pCI110 series of Vmw110 expression plasmids (see above). Successful
transfer was monitored by detection of the novel FspI site,
by DNA sequence analysis of the mutagenized region and, for the mutants
M1, M2, and M4, by extensive sequence analysis of the coding region of the C-terminal portion of Vmw110.
Expression and purification of GST fusion proteins.
Bacteria
harboring GST fusion protein expression plasmids were grown from
freshly purified colonies in 100-ml cultures of yeast extract tryptone
broth. When the optical density at 450 nm (OD450) reached
about 0.6, IPTG (isopropyl-
-D-thiogalactopyranoside) was
added to a final concentration of 0.1 mM to induce expression. After
2 h, cells were harvested by centrifugation and resuspended in 2 ml of phosphate-buffered saline (PBS). The bacteria were lysed with a
soniprobe (Branson sonifier 450), and Triton X-100 was then added to a
final concentration of 1%. After a 10-min incubation on ice, insoluble
debris were removed by centrifugation (Sorvall SS34 rotor) at 9,500 rpm
for 5 min. Aliquots (each, 300 µl) of supernatant were mixed with 50 to 100 µl of a 50% slurry of glutathione-agarose beads which had
been preswollen for 1 h and washed in PBS. The beads were
incubated in the extract at 4°C for 1 h with continuous mixing,
harvested by brief centrifugation, washed three times in PBS, and
stored on ice as a 50% slurry. In all GST pull-down experiments, the
amounts of the fusion proteins bound to the beads were estimated by
Coomassie staining of a sodium dodecyl sulfate (SDS)-polyacrylamide gel
loaded with small samples of the bead preparations. Subsequent binding
experiments used amounts of beads normalized for the amount of each
fusion protein and maintenance of the total quantity of
glutathione-beads by the addition of uncharged beads where necessary.
Analysis of cellular proteins bound to GST fusion proteins.
Freshly prepared glutathione-agarose beads with bound and normalized
GST fusion proteins (30 µl of a 50% slurry) were mixed with 300 µl
of labelled cell protein extract to which NaCl had been added to a
final concentration of 0.5 M. Initially, all extracts were incubated
for 1 h at 4°C with continuous mixing with beads linked to the
GST protein expressed by vector plasmid pGEX2TN3 in order to reduce
background. After removal of these beads by centrifugation, the
precleared extracts were incubated with 30 µl of a 50% slurry of the
appropriate GST fusion protein beads and a negative GST bead control,
again for 1 h at 4°C with continuous mixing. The beads were
harvested by brief centrifugation, then washed three times in a buffer
containing 50 mM Tris-HCl (pH 8.0), 0.5 mM NaCl, 1 mM EDTA, and 0.5%
Nonidet P-40 (NP-40). Protease inhibitors phenylmethylsulfonyl
fluoride, bestatin, and leupeptin were used in the wash buffer at
concentrations of 1 mM, 40 µg/ml, and 0.5 µg/ml, respectively.
Protein complexes were eluted from the beads with sequential washes
(each, 20 µl) of 50 mM reduced glutathione in 0.25 M Tris-HCl (pH
7.0). Elution was at 25°C for 15 min. The supernatants containing
fusion protein complexes were mixed with SDS-acrylamide gel loading
buffer and boiled.
Virus infection and labelling of cellular proteins.
HeLa
cells were seeded at 80% confluency 24 h before infection with
viruses at a multiplicity of 5 PFU per cell. Extracts from
virus-infected cells for immune precipitation experiments were prepared
16 h later as described below. Labelling of cellular proteins
was conducted by removing the growth medium, washing the cells
with PBS, and then adding PBS with [35S]methionine
at a concentration of 100 µCi/ml (15 ml per 140-mm-diameter plate). The cells were harvested 2 h later for extract preparation.
Preparation of cell extracts.
Infected cells for immune
precipitation experiments were washed in PBS and harvested in a buffer
containing 50 mM Tris-HCl (pH 8.5), 200 mM NaCl, 0.1 mM zinc acetate,
and 10 mM 2-mercaptoethanol (160 µl for the cells from an
80-mm-diameter plate). The cells were lysed with either 10 strokes of a
small Dounce homogenizer or brief sonication in a sonibath, and the
debris were pelleted by centrifugation (Sorvall SS35 rotor) at 10,000 rpm for 15 min. Uninfected cell extracts for use in binding experiments
in vitro were prepared by resuspending the cells (either unlabelled or labelled with [35S]methionine, as appropriate and as
described in the text) in 50 mM HEPES (pH 7.5)-50 mM NaCl-0.1% NP-40
(1 ml per 140-mm-diameter plate). The cells were sonicated in a
sonibath, and the debris were pelleted by centrifugation with a Beckman
bench top centrifuge at 3,000 rpm for 10 min.
Immune precipitations.
Crude extracts from 6-h-infection
samples were made up to a volume of 0.6 ml, maintaining the
concentration of NaCl at 200 mM and adding NP-40 to a final
concentration of 0.2%. MAb 11060 (2 µl) and sheep anti-mouse
immunoglobulin (Ig) serum (5 µl) were added and mixed on a rotary
shaker at 4°C for 3 h. Then 60 µl of protein A-Sepharose
(Sigma) equilibrated in the same buffer was added and the incubation
was continued for a further hour. The Sepharose beads were pelleted and
washed three times with 0.6 ml of buffer (50 mM Tris-HCl [pH 8.5],
0.2 M NaCl, 10 mM 2-mercaptoethanol, 0.1 mM zinc acetate, 0.2% NP-40).
The beads were then taken up in SDS-acrylamide gel loading buffer and boiled.
SDS-gel electrophoresis and Western blotting.
Protein
samples were loaded onto 7.5% or 10% 30:1 acrylamide-bis-acrylamide
gels prepared for use in the BioRad MiniProtein II apparatus. Gels were
either fixed and stained or used for Western blotting according to the
methods recommended by the supplier. Nitrocellulose filters with
immobilized blotted proteins were blocked with 5% dried milk in PBS
containing 0.1% Tween 20, incubated with primary antibodies in PBS
containing 0.1% Tween 20 with 2% dried milk for 2 to 4 h, and
then washed thoroughly and incubated with horseradish
peroxidase-conjugated secondary antibodies (goat anti-rabbit Ig or
sheep anti-mouse Ig; Sigma) prior to detection by the Amersham ECL method.
Immunofluorescence.
HEp2 cells were seeded at a density of
0.5 × 105 cells per ml into 24-well Linbro dishes
containing glass coverslips. The cells were infected with wild-type and
mutant viruses at the multiplicities indicated in the figure legends.
After either 2 or 4 h, the cells were washed with PBS, fixed with
formaldehyde (5% vol/vol of stock solution in PBS containing 2%
sucrose) and permeabilized with 0.5% NP-40 in PBS with 10% sucrose.
The primary antibodies were diluted in PBS containing 1% NBCS.
Anti-Vmw110 monoclonal antibody 11060 was used at a dilution of
1/2,000, and anti-PML rabbit serum r8 was used at 1/1,000. Goat
anti-mouse fluorescein isothiocyanate-labelled and goat anti-rabbit
tetramethyl rhodamine isothiocyanate-labelled secondary antibodies
(Sigma) were used at dilutions of 1/100. After staining, the coverslips
were mounted and examined with a Zeiss LSM 510 confocal microscopy
system with a ×63 NA 1.4 objective lens. Data collection was performed
under conditions of no detectable channel overlap, and the images
were processed by using Photoshop.
Antibodies.
Immune precipitations were conducted with MAb
11060, which recognizes and strongly interacts with an epitope between
residues 20 and 105 of Vmw110. MAb 10503 recognizes an epitope in the
C-terminal 140 residues of Vmw110 (10). Polyclonal rabbit
serum 95 is directed against the RING finger domain of Vmw110
(10). Anti-PML rabbit serum r8 (1) was used to
detect PML. Rabbit serum r201 was generated by using a branched peptide
containing the 16 C-terminal residues of HAUSP (13).
Transfections and CAT assays.
The ability of Vmw110 and
mutant derivatives to activate gene expression in transfected cells was
determined by using plasmid pSS80 as a reporter (this plasmid carries
the chloramphenicol acetyltransferase [CAT] gene linked to the ICP6
promoter region) essentially as described previously (12).
In this series of experiments Cos7 cells were used, and Vmw110 and
mutant derivatives were expressed from the pCI series of plasmids, as
described above. Calcium phosphate-mediated transfection was used as
described previously (12). The transfection experiments were
repeated on at least four independent occasions in parallel with
positive and negative controls.
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RESULTS |
Definition of the minimal HAUSP binding domain in
Vmw110.
We have previously shown that a GST fusion protein
including the C-terminal region of Vmw110 from residues 594 to 775 binds strongly to HAUSP in vitro and that shorter fragments (residues 633 to 775, 680 to 775, and 696 to 775) do not (29, 30).
Therefore, the Vmw110 region between residue 594 and residue 632 contains residues that are essential for binding to HAUSP. To determine the nature of these residues and to define the minimal segment of
Vmw110 required for HAUSP binding, plasmids were constructed that
expressed GST fusion proteins with shorter segments of Vmw110, as
summarized in Table 1. Extracts
containing these proteins were prepared from induced bacteria,
and GST pull-down assays were conducted with glutathione agarose beads
charged with these proteins. The positive control was pGEXE52,
expressing residues 593 to 775, and the negative control was GST alone.
The results are summarized in Fig.
1. Shortening of the expressed segment from the N-terminal end (as in plasmids pGEXE4 and pGEXE9) showed that
residues between 594 and 617 were dispensable for binding to HAUSP
(Fig. 1A). Truncation of the Vmw110 sequences at the C-terminal end
showed that sequences downstream of 681 were not essential for binding
(Fig. 1B), and the shortest binding-positive segment in this assay
contained residues 594 through 646 (pGEXE52AvaI; Fig. 1C). Further
truncation of this segment to include only residues 594 to 638 (pGEXE23X) significantly weakened the binding, and no binding was
observed with the segment containing 594 to 632 (pGEXE58X; Fig. 1D).
Taken together, these data show that Vmw110 residues 594 to 646 (and
probably 618 to 638) are sufficient for binding to HAUSP in vitro and
that essential residues lie between residue 618 and residue 632. These
data are consistent with results later obtained by coimmune
precipitation of HAUSP and Vmw110 from virus-infected cell extracts,
except that truncation at residue 646 significantly reduced HAUSP
binding in the latter system (see below).
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FIG. 1.
Binding of HAUSP to C-terminal fragments of Vmw110 in
GST pull-down assays. Extracts of cellular proteins labelled with
[35S]methionine were incubated with glutathione-agarose
beads charged with GST or Vmw110 fusion protein derivatives as
described in Materials and Methods. Bound proteins were eluted with
reduced glutathione in two sequential steps (labelled 1 and 2 in panel
A) and analyzed by SDS-7.5% polyacrylamide gel electrophoresis and
autoradiography. Each set of experiments included a negative control
with GST alone (GST) and the positive control fusion protein expressed
by GEXE52 (594-775). The left-hand track in each panel is a sample of
the extract, and the arrow points to the position of the HAUSP band.
The identification of the HAUSP band at approximately 130 kDa has been
described in detail previously (29, 30). (A) The results
obtained with pGEXE4 (615-775) and pGEXE9 (618-775). (B, C, and D)
Only the relevant parts of the gels obtained by using proteins
expressed by the construct pGEXE52PmlI (594-713) and
pGEXE52RsaI (594-680), the construct pGEXE52AvaI (594-646),
and the constructs pGEXE23X (594-638) and pGEXE58X (594-633),
respectively.
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Disruption of HAUSP binding in vitro in mutants carrying single and
double amino acid substitutions in Vmw110.
Of the 21 Vmw110 amino
acids between residues 618 and 638, 7 are charged; in particular, there
are three groups of positively charged doublets (Fig.
2). Comparison with the corresponding
sequence from the HSV-2 homologue protein showed precise conservation
of the charged and intervening residues (data not shown), so we
considered that it was possible that these residues contributed to the
HAUSP binding interface. A series of single and double amino acid
substitutions in pGEXE52 were created by site-directed mutagenesis, as
summarized in Fig. 2. The choice of replacement residues was determined
so as to alter the charge but maintain the size of the residue as closely as possible. The mutant fusion proteins were used in GST pull-down assays, and in this experiment bound HAUSP was detected by
Western blotting with rabbit serum r201. Probing of the gel with
anti-Vmw110 MAb 10503 showed that the amounts of GST fusion proteins
used were equivalent (Fig. 3B). The
binding results (Fig. 3A) defined at least two residues, lysine 620 (mutant M4) and lysine 624 (mutant M1), that were crucial for HAUSP
binding. Mutation of arginine 623 (mutant M2, also altered in mutant
M1) indicated that this residue was not required for efficient binding.
Histidine 627 was also not required for binding (mutant M6), while
mutation of arginine residues 619 and 626 caused reproducible
reductions in binding activity (mutants M5 and M7, respectively). These
data do not give a complete definition of the Vmw110 residues that are
required for HAUSP binding, but they do allow the construction of
minimally mutated versions of Vmw110 which would be expected to be
HAUSP binding deficient.
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FIG. 2.
Mutagenesis of selected charged residues within the
minimal HAUSP binding region of Vmw110. The upper three lines show the
amino acid (aa) and coding sequences (seq.) of residues 616 through 629 of Vmw110. The next three lines show the relevant changes in the
mutagenic oligonucleotides (oligo4, oligo5, and oligo6). Uppercase
letters denote base changes which were present invariably, and
lowercase letters indicate positions where equal proportions of normal
and mutant nucleotide precursors were included during synthesis, so
that individual single and double mutants could be isolated in the same
mutagenesis experiment. The actual mutagenic oligonucleotides included
greater lengths of flanking sequence than shown here, but these regions
did not contain any substitutions. The line labelled Replace indicates
the expected amino acid substitution if the mutagenic nucleotide change
is present and also the presence of the FspI site (FspI) in
residues 621 and 622. Below are shown the actual amino acid sequences
of mutants that were isolated. The presence of the mutations was
detected in the M13 isolates, then confirmed by DNA sequencing after
transfer of the mutant fragment to plasmids of the p110 series (see
Materials and Methods).
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FIG. 3.
Binding of HAUSP to GST-Vmw110 fusion proteins with
substitution mutations with the minimal HAUSP binding region. GST
pull-down experiments were conducted as described in the legend to Fig.
1 and in Materials and Methods by using unlabelled extracts of cellular
proteins. Proteins remaining bound to the beads were separated by
SDS-7.5% polyacrylamide gel electrophoresis and transferred to
nitrocellulose membranes by Western blotting. Bound HAUSP was detected
by probing with rabbit serum r201 (which detects a number of other
bands in addition to the major band of HAUSP). (A) The left-hand track
contains a sample of the extract, and the adjacent lane shows the
result obtained by using the fusion protein expressed by pGEXE52. The
results obtained with the mutants of the M series, whose details are
given in Fig. 2, are shown with the position of HAUSP indicated by the
arrow. (B) The relevant portion of the same blot reprobed with MAb
10503 to compare the quantities of the fusion protein used.
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Construction of viruses expressing proteins with deletions and
substitutions in the C-terminal region of Vmw110.
To explore
the functional significance of Vmw110-HAUSP interaction, a series of
plasmids was constructed, which contained a selection of the deletion
and substitution mutations in the C-terminal region of Vmw110 as used
in the GST fusion protein experiments described above. A number of
these plasmids were cotransfected with infectious DNA of the Vmw110
deletion mutant dl1403 in order to construct viruses which
expressed mutant Vmw110 proteins with defined lesions in the HAUSP
binding region. The desired mutant viruses were identified by Southern
blotting, and stocks were prepared after three rounds of plaque
purification. The viruses expressed Vmw110 proteins of the expected
sizes (see Fig. 4 and 5) and had the predicted restriction enzyme
fragment patterns (data not shown). A summary of the properties of
these viruses is given in Table 2.
Extracts from cells infected with these mutant viruses were prepared
and used in immune precipitation reactions to determine
whether
mutations caused defects in HAUSP binding similar to those
observed in
the GST pull-down experiments described above. The
results were largely
consistent both with previously published
observations (
29,
30) and with the in vitro binding data (see
Fig.
1 and
3).
The deletion mutant A78 (
592-647) reduced HAUSP
binding
to background levels (Fig.
4A). A
quantitative difference
between the in vitro binding and the immune
precipitation results
was that the viral truncation mutant A8X
exhibited substantially
reduced binding (Fig.
4A and B) while its
equivalent GST fusion
protein (expressed by pGEXE52AvaI) appeared
to bind almost as
efficiently as the complete C-terminal region
expressed by pGEXE52
(Fig.
1C). It is possible that the large
amounts of fusion protein
used in the in vitro assays mask reductions
in binding affinity
that are revealed in the more sensitive immune
precipitation assay.
The truncation mutant E58X had minimal binding
activity (Fig.
4B). Perhaps most importantly, the substitution
mutations M1 and
M4, which decreased binding in vitro to background
levels, resulted
in substantial reductions in HAUSP binding in infected
cell extracts
(Fig.
5). In contrast, the
M2 mutation had little effect in both
assays. These results confirm the
importance of this region of
Vmw110 for HAUSP binding. The
plasmids and viruses constructed
in these experiments allow a thorough
analysis of the contribution
of HAUSP binding to Vmw110 function.
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FIG. 4.
Coimmune precipitation of HAUSP with Vmw110 from
extracts of cells infected with wild-type and Vmw110 mutant
viruses. HeLa cells were mock infected (mock) or infected
with wild-type virus (1-775) and with the deletion-carrying
mutant viruses A78 (del 592-647) and A8X (1-646) (A) and with
the deletion mutants A8X and E58X (1-632) (B). Extracts were
prepared and used for immune precipitation of Vmw110 as described in
Materials and Methods. Panel A shows precipitated proteins (IP)
analyzed alongside samples from the corresponding extracts (ex) by
Western blotting. In panel B, only the precipitated proteins
are shown. The upper part of each panel shows the relevant portion of
the filter probed with anti-HAUSP serum r201, while the lower part
shows the same filter probed with anti-Vmw110 serum r95. The arrows
point to HAUSP.
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FIG. 5.
Coimmune precipitation of HAUSP with Vmw110 from
extracts of cells infected with wild-type and Vmw110 substitution
mutant viruses. An experiment similar to that illustrated in Fig. 5 was
conducted with wild-type virus positive control (1-775), the mutant
E52X negative control (1-593), and the substitution-carrying mutant
viruses M1, M2, and M4. The upper part of the figure shows proteins
detected by Western blotting by using anti-HAUSP serum r201 in a sample
of cell extract and in anti-Vmw110 immune precipitates from
mock-infected (mock) and virus-infected cells as indicated. The arrow
indicates the position of HAUSP. The lower part shows the
presence of Vmw110 proteins in the immune precipitates after reprobing
of the filter with anti-Vmw110 serum r95.
|
|
The ability to bind to HAUSP contributes to the activation of gene
expression by Vmw110.
Once simple mutations which disrupt HAUSP
binding by Vmw110 in vitro were defined, it was possible to determine
the effects of these mutations on the ability of the protein to
activate gene expression in transfected cells. The results were
compared with those obtained by using other more extensive alterations
of the C-terminal region of Vmw110. Cotransfection of Cos7 cells with a
reporter plasmid (pSS80, which expresses CAT from the ICP6 promoter) and pCI110 (which expresses wild-type Vmw110 from the HCMV promoter in
the vector pCIneo) resulted in a 9.6-fold increase in CAT activity (Fig. 6). This was reduced to only
2.3-fold by deletion of the RING finger region in plasmid pCIFXE; this
region has been shown previously to be of prime importance for Vmw110
activity in this type of assay (7). On the basis of the
HAUSP binding data presented above and previously published mapping of
the self-multimerization domain of Vmw110 (4, 30), the
proteins expressed by the various C-terminal region Vmw110 deletion
mutants can be classified as follows: HAUSP binding competent but
multimerization deficient (those expressed by pCIA8X and pCID13);
HAUSP binding deficient but multimerization competent (pCID12 and
pCIA78); and neither HAUSP binding competent nor multimerization
competent (pCIE52X and pCIE58X). All of these deletions reduced
activation of gene expression by Vmw110 (Fig. 6), suggesting that the
abilities of Vmw110 to bind to HAUSP and to multimerize contribute to
its activity. However, the reductions caused by these deletions were
not as great as that resulting from loss of the RING finger. In
contrast, the substitution-carrying mutants pCIM1 and pCIM4 had
substantially reduced activities, while mutant pCIM2 as expected
activated gene expression as efficiently as wild-type pCI110. Western
blotting of extracts of cells transfected with this series of plasmids indicated that the mutant proteins were expressed to similar levels (Fig. 6, bottom).
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FIG. 6.
Activation of gene expression by Vmw110 and derivatives
with mutations in the C-terminal region. Cos7 cells were cotransfected
with reporter plasmid pSS80 (ICP6 promoter linked to CAT) and Vmw110
expression plasmids. The negative control is the vector pCIneo, and all
CAT activities are given as fold activation over this basal level. The
data are averages for at least four independent transfection assays.
The nature of the mutations carried by E52X, E58X, A8X, D12, A78, M1,
M2, M4, and FXE is shown in Table 2. The deletion carried by D13
(deletion of residues 633 through 680) affects the multimerization and
ND10 binding of Vmw110 but not its ability to bind to HAUSP
(29). The lower part of the figure shows a Western blot of
total proteins of cells, transfected in parallel with the same
plasmids, probed with anti-Vmw110 MAb 11060.
|
|
A puzzling feature of these results from transfection assays is
the relatively modest effect of complete deletion of the
C-terminal
region of Vmw110 (pCIE52X) compared to the M1 and M4 point
mutations
and other smaller deletions. There is no clear explanation of
this result, but the following considerations of transfection
assays
and the effects of Vmw110 may be relevant. First, the viral
E52X
deletion mutation causes a defect in PML isoform degradation
in the
early stages of infection, but this is a kinetic defect
in that at
later times at least some E52X-induced degradation
occurs
(
14). If this process is directly related to Vmw110
activity,
the reduced rate of E52X activity might be sufficient in the
much
longer timescale of a transfection assay to induce significant
activation of gene expression. On the other hand, the E52X mutant
protein is actually as efficient as wild-type virus in inducing
the
loss of CENP-C, whereas the M1 mutant appears to be less efficient
than
the wild type (
16). Although the significance of the effect
of Vmw110 on CENP-C in terms of gene expression remains unknown,
this
finding raises the possibility that the effect of Vmw110
on any
particular cellular target may be varied by deletion or
point
mutation in unpredictable ways. Whatever the explanation
of the
unexpectedly high activity of the E52X mutation in this
transfection
assay system, the results obtained with the M-series
point mutant
plasmids are consistent with the hypothesis that
the ability to bind to
HAUSP contributes to the activation of
gene expression induced by
Vmw110 in transfected
cells.
The relationship between HAUSP binding and ND10 disruption by
Vmw110.
Previous data have shown that many deletion mutations in
the C-terminal region of Vmw110 result in failure to localize to and
disrupt ND10 (11, 30), but mutations that specifically affect HAUSP binding have not been studied in this respect in any
detail. Therefore, HEp-2 cells were infected with a panel of deletion-
and substitution-carrying mutant viruses, and the localization of
Vmw110 and PML (to detect ND10) was examined by immunofluorescence at 2 and 4 h postinfection. After 2 h of
infection (Fig. 7), the localization of
wild-type and FXE mutant proteins was as previously reported
(27); discrete punctate accumulations were seen within
a diffusely distributed background (Fig. 7A and C). At this stage of
infection, neither the wild type nor the FXE mutant caused any obvious
systematic change in the distribution of PML in ND10 (compare the
infected and uninfected cells in Fig. 7B and D), and many of the
localized accumulations of Vmw110 corresponded to the sites of ND10
(compare horizontal pairs of panels). Mutants D12, A78, M1, M2, and M4
all gave results similar to that for the wild-type protein at 2 h.
The mutants which differed were A8X (Fig. 7E) and E58X (not shown),
which gave a diffuse nuclear distribution similar to those of
previously described viruses E52X, D13, and D14 (27, 30).
Since the A78 and D12 deletion mutations and the M1 and M4 substitution
mutations remove sequences required for HAUSP binding, it can be
concluded that the ability of Vmw110 to bind to HAUSP is not essential
for its localization to ND10.
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FIG. 7.
Distribution of wild-type and mutant Vmw110 proteins in
HEp-2 cells 2 h after the start of infection. Cells on coverslips
were infected with the HSV-1 strain 17+ (A and B) and with mutant
derivatives FXE (C and D), A8X (E and F), D12 (G and H), A78 (I and J),
M1 (K and L), M2 (M and N), and M4 (O and P). Each pair of panels shows
the same field of cells stained for Vmw110 (MAb 11060) (left) and PML
(r8, to indicate ND10) (right). The bar in P corresponds to 10 µm.
|
|
The differences between the mutants were more marked after 4 h of
infection (Fig.
8). By that time,
wild-type Vmw110 had caused
the complete disruption of ND10 (Fig.
8A
and B), while the RING
finger mutant FXE remained colocalized with PML
(C and D). The
Vmw110 deletion mutant proteins expressed by viruses A8X
(E) and
E58X (data not shown) again gave diffuse nuclear staining
patterns,
and ND10 was extensively retained in the infected cells (F).
By
4 h after the start of infection, virus A78 gave an
intermediate
phenotype, with some punctate staining in some cells (I)
and some
infected cells retaining some ND10 (J). Virus D12 (G) gave a
greater
degree of punctate staining than A78, but again some cells
retained
a few ND10 (H). The HAUSP-binding-proficient M2 point mutant
behaved
exactly like the wild type, inducing the complete loss of PML
in ND10 at 4 h (M and N), but the HAUSP-binding-negative mutants
M1 and M4 showed two interesting differences in this assay. First,
although many infected cells had lost all ND10 by this time, it
was
noticeable that some infected cells retained at least some
ND10 (L and
P). It should be noted that the results of this type
of experiment vary
with time, from cell to cell, and with cell
type (see below), so it is
difficult to compare the relative kinetics
of ND10 disruption with
precision. However, it is clear that the
HAUSP-binding-negative mutants
retain the ability to disrupt ND10.
The second difference from the wild
type exhibited by the M1 and
M4 proteins was their accumulation in
large cytoplasmic foci in
many cells (K and O). This effect became more
marked as infection
progressed (data not shown).
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FIG. 8.
Disruption of ND10 by wild-type and mutant Vmw110
proteins. Coverslips were processed for immunofluorescence 4 h
after the start of infection. All other details are exactly as
described for Fig. 7.
|
|
The ability of Vmw110 to bind to HAUSP contributes to the
efficiency of virus replication in tissue culture.
In the
experiments described above we have shown that the C-terminal region of
Vmw110 is complex and responsible (at least in part) for a number of
phenomena, including localization to ND10, disruption of ND10, binding
to HAUSP, and (as deduced by comparison with previous data)
self-multimerization. The conclusions that emerge from this study of
multiple deletion and substitution mutations in this region are that
localization to ND10 requires sequences that have not been separated
from the mapped self-multimerization domain and that efficient
disruption of ND10 requires the ability of Vmw110 to localize to ND10
but not to bind to HAUSP. However, all the mutations are to some extent
deleterious for the ability of Vmw110 to activate gene expression in
transfected cells. To investigate the effects of these mutations on
virus replication, single-step growth curve experiments were conducted
with BHK cells and all the available virus mutants and the results were
compared with those for strain 17+ (wild type) and the
RING-finger-deletion-carrying mutant FXE. The results obtained with the
mutant viruses (Fig. 9) were similar to
those obtained in previous studies; in particular, the moderate growth
defect caused by the A78 mutation parallels that seen previously with
the D12 deletion mutation (30), while the E58X truncation
mutation had an effect similar to that of the more extensive E52X
deletion. However, the most important conclusion is that the M series
of substitution mutations caused growth defects which reflected their
reduction of HAUSP binding by Vmw110. That a single amino acid
substitution at Vmw110 residue 620 can reduce HAUSP binding to
background levels and cause a significant reduction in virus growth
provides compelling evidence that the ability of Vmw110 to bind to
HAUSP contributes to its biological properties.
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FIG. 9.
Growth curves of the HSV-1 strain 17+ and derivatives
with lesions in Vmw110. BHK cells were infected with the viruses at 1 PFU per cell, replicate plates were harvested 4, 8, 16, and 24 h
later, and progeny virus was titrated on BHK cells. Panels A and C show
the results obtained with the viruses constructed for this study, with
wild-type virus, and with the Vmw110 RING finger deletion mutant virus
FXE. For comparison and completeness, panel B shows the results
obtained with the complete C-terminal region deletion mutant, E52X, and
the HAUSP-binding-region-deletion mutant, D12 (taken from reference
30). The genotypes of the viruses are given in Table
2. The data are averages of two independent experiments.
|
|
| |
DISCUSSION |
This paper presents a thorough analysis of the role of
HAUSP binding in Vmw110 activity in transfected and infected cells. We have identified single amino acid residues within a small region of
Vmw110 which are required for HAUSP binding, and we have shown that
removal of this region or alteration of specific residues within it
reduces Vmw110 activity. The results obtained with the substitution
mutants M1 and M4 are particularly striking. However, it is clear that
other factors are also involved in Vmw110 activity.
An understanding of the role of Vmw110 in virus infection is made
difficult by both the complexity of the phenotypes of Vmw110 mutants
and the presence of multiple domains within the protein that contribute
to its functions. The defect caused by lack of functional Vmw110 is
cell type, cell cycle, and multiplicity dependent (2, 34).
Therefore, by definition, the effect of Vmw110 varies among individual
cells in a single experiment, because each cell varies in its stage in
the cell cycle and the dose of virus that it receives. Since the defect
can be overcome at high multiplicity, infection with a
sufficient amount of virus to enable viral gene expression to be
readily detectable (by Western or Northern blotting, for example)
circumvents the requirement for Vmw110, at least to some extent.
Furthermore, once the lytic cycle has been established the role
of Vmw110 appears to be dispensable since equal numbers of progeny
virus particles are produced (8). Indeed, growth curves of the type shown in Fig. 9 in reality reflect the subsequent probability of initiation of plaque formation by the progeny virus rather than the total amount of virus particles produced. For these
reasons, simple measurement of viral gene expression in productive
infection is a problematic method of gauging Vmw110 activity.
Dissecting this complex phenotype is further complicated by the nature
of Vmw110 itself. It contains sequences required for self-multimerization, for transport to the nucleus, for localization at
ND10, for disruption of ND10, and for binding to HAUSP. Of these, the
RING finger domain appears to be the most important, since RING finger
mutants do not disrupt ND10, do not alter the stability of a number of
cellular proteins, are very poor activators of gene expression in
transfection assays, and form plaques as inefficiently as a null
mutant. This paper shows that the HAUSP binding region of Vmw110 also
affects activation of gene expression in transfection assays and plaque
forming efficiency (as indicated by a single-step growth curve), but in
HEp-2 cells the HAUSP binding mutants colocalize with PML and disrupt
ND10 almost as well as the wild type. At first sight, this finding
presents an anomaly since in all other respects ND10 disruption
correlates with Vmw110 activity, and it is an attractive hypothesis
that the mechanisms which result in the disruption of ND10 underlie the
biological activity of Vmw110. A possible explanation of this paradox
lies in the cell type specificity of the Vmw110 mutant phenotype. We have previously shown that, compared to the results in HEp-2 cells (Fig. 8), the HAUSP-binding-defective mutant D12 disrupted ND10 inefficiently in BHK cells (30). Recent studies on the
correlation between ND10 disruption and the Vmw110-induced loss of the
PML isoforms have confirmed that in BHK cells mutant D12 is indeed defective in ND10 disruption, and this correlates with inefficient degradation of the PML isoforms (14) and its reduced growth in BHK cells (Fig. 9). Furthermore, the D12 mutant disrupts ND10 more
efficiently in HFL cells, and this correlates with improved growth in
this cell type (14).
The picture emerging from this paper and other recent work is that a
major biochemical function of Vmw110 is the control of the stability of
a number of specific cellular proteins. A likely scenario is that one
or more of the target proteins is involved in a pathway that promotes
the establishment of a quiescent state of the incoming viral genome,
and therefore its Vmw110-induced loss would increase the probability of
the onset of the lytic cycle. The conclusion of this paper that the
ability to bind to HAUSP contributes to the biological functions of
Vmw110 is, in principle, consistent with the idea that protein
stability pathways play a key role in control of HSV-1 infection. The
next goals must be to catalogue the cellular proteins which are
affected by Vmw110 and then to determine which of them lie at the heart of Vmw110 activity.
| |
ACKNOWLEDGMENTS |
We are grateful for the helpful criticism of the manuscript by
Duncan McGeoch and for the supply of antibodies by Paul Freemont (ICRF,
London, United Kingdom) and Roel van Driel (E. C. Slater Institute,
Amsterdam, The Netherlands).
This work was supported by the Medical Research Council.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: MRC Virology
Unit, Institute of Virology, Church St., Glasgow, Scotland G11 5JR,
United Kingdom. Phone: 141 330 3923. Fax: 141 337 2236. E-mail:
r.everett{at}vir.gla.ac.uk.
Present address: Department of Biochemistry, University of Dundee,
Dundee DD1 5EH, Scotland.
| |
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Journal of Virology, January 1999, p. 417-426, Vol. 73, No. 1
0022-538X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
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