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Journal of Virology, February 2000, p. 1200-1208, Vol. 74, No. 3
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Characterization of the trans-Activation
Properties of Equine Herpesvirus 1 EICP0 Protein
Dawn E.
Bowles,
Seong K.
Kim, and
Dennis J.
O'Callaghan*
Department of Microbiology and Immunology,
Louisiana State University Health Sciences Center, Shreveport,
Louisiana 71130-3932
Received 30 July 1999/Accepted 2 November 1999
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ABSTRACT |
The EICP0 protein of equine herpesvirus 1 (EHV-1) is an early,
viral regulatory protein that independently trans-activates EHV-1 immediate-early (IE), early, 
1 late, and 2 late promoters. To assess whether this powerful trans-activator functions
in conjunction with three other EHV-1 regulatory proteins to activate
expression of the various classes of viral promoters, transient
cotransfection assays were performed in which effector plasmids
expressing the EICP22, EICP27, and IE proteins were used either singly
or in combination with an EICP0 effector construct. These analyses
revealed that (i) independently, the EICP0 and IE proteins are powerful trans-activators but do not function synergistically, (ii)
the IE protein inhibits the ability of the EICP0 protein to
trans-activate the IE, 1 late, and 2 late promoters,
(iii) the EICP22 and EICP0 proteins do not function together to
significantly trans-activate any EHV-1 promoter, and (iv)
the EICP27 and EICP0 proteins function synergistically to
trans-activate the early and 1 late promoters. A panel
of EICP0 truncation and deletion mutant plasmids was generated and used
in experiments to define the domains of the 419-amino-acid (aa) EICP0
protein that are important for the trans-activation of each
class of EHV-1 promoters. These studies revealed that (i)
carboxy-terminal truncation mutants of the EICP0 protein exhibited a
progressive loss of trans-activating ability as increasing
portions of the carboxy terminus were removed, (ii) the amino terminus of the EICP0 protein containing the RING finger (aa 8 to 46) and the
acidic region (aa 71 to 84) was necessary but not sufficient for
activation of all classes of EHV-1 promoters, (iii) the RING finger was
absolutely essential for activation of EHV-1 promoters, since deletion
of the entire RING finger motif (aa 8 to 46) or a portion of it (aa 19 to 30) completely abrogated the ability of these mutants to activate
any promoter tested, (iv) the acidic region contributed to the ability
of the EICP0 protein to activate the early and 1 late promoters, and
deletion of the acidic region enhanced the ability of this mutant to
activate the IE promoter, (v) the carboxy terminus (aa 325 to 419),
which is rich in glutamine residues, was dispensable for the EICP0
trans-activation function, (vi) a motif resembling a
nuclear localization signal (aa 289 to 293) was unnecessary for the
EICP0 protein to trans-activate promoters of any temporal
class, and (vii) the EICP0 protein was phosphorylated during infection,
and deletion of the serine-rich region (aa 210 to 217), a potential
site for phosphorylation, reduced by more than 70% the ability of the
EICP0 protein to activate the 2 late class of promoters.
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INTRODUCTION |
Equine herpesvirus 1 (EHV-1), an
important pathogen of the horse, causes rhinopneumonitis, spontaneous
abortions in pregnant mares, and myeloencephalitis (1, 35).
The 77 genes of EHV-1 are transcribed in an ordered and temporally
controlled cascade termed immediate-early (IE), early (E), and late (L)
(4, 17, 18). Five EHV-1 regulatory proteins (EICP22, EICP27,
EICP0, IE, and E-TIF [EHV-1 
-trans-inducing protein])
are known to control the specific transcription of viral genes (2,
20, 22, 26, 27-29, 35, 40-43, 47).
The sole IE gene, the first gene to be transcribed during infection,
encodes the key regulatory protein of EHV-1 (3, 19, 40). IE
gene transcription occurs in the absence of viral protein synthesis and
is induced by E-TIF (7, 28, 29, 37). The IE protein
activates expression of the early promoters, autoregulates expression
of its own promoter (40), and is essential for EHV-1 replication, since deletion of both copies of the IE gene renders the
virus unable to grow on noncomplementing cells (16).
The second set of genes to be transcribed during an EHV-1 infection are
early genes, which encode additional viral regulatory proteins (EICP0,
EICP22, and EICP27), as well as proteins involved in the replication of
the viral genome (2, 4, 20, 21, 46). Early gene
transcription requires the presence of the IE protein and occurs before
the initiation of viral DNA synthesis. Late genes are the last set to
be transcribed, and the majority encode viral structural proteins
(4). The late genes can be further divided into two
subclasses: (i) 1 or "leaky late" genes, whose expression begins
prior to viral DNA replication but does not reach maximal levels until
after the onset of viral DNA replication and (ii) 2 or "true
late" genes, whose synthesis is totally dependent on viral DNA replication.
The EICP0 protein is the only EHV-1 regulatory protein that
independently activates all classes of viral promoters (IE, early, 1
late, and 2 late) in transient transfection chloramphenicol acetyltransferase (CAT) assays (2). Our present
understanding of EHV-1 gene regulation suggests that the EICP0 protein
is important in the switch from early to late gene expression. The
relative amounts of the IE and EICP0 proteins appear to be a factor in this temporal switch, since these two regulatory proteins have an
antagonistic relationship, as we previously reported (25). The goals of the studies presented here were to determine whether the
EICP0 protein functions in conjunction with other EHV-1 regulatory proteins (IE, EICP22, and EICP27) and to define the domains of the
EICP0 protein that are important for its trans-activation function. Synergy among some of the EHV-1 regulatory proteins has been
described previously. For example, the IE protein functions in
conjunction with the EICP22 or EICP27 early regulatory proteins to
up-regulate expression from early and 1 late promoters (22, 42,
47). The EICP22 protein increases the ability of the IE protein
to bind to its cognate DNA binding site, thereby enhancing the ability
of the IE protein to activate transcription from different promoters
(26, 27). The precise mechanism by which the EICP27 accessory protein functions to increase IE protein
trans-activation is unknown and is currently under investigation.
Studies presented here indicate that the IE and EICP0 proteins do not
function synergistically but instead function antagonistically. The
EICP27 protein, but not the EICP22 protein, has the ability to enhance
EICP0 trans-activation of early and 1 late promoters. In
addition, mutational analyses of the EHV-1 EICP0 protein indicated that
several regions of this protein are important for its
trans-activation function, including the RING finger, the
acidic, and the serine-rich regions.
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MATERIALS AND METHODS |
Cells and virus.
Cultures of L-M (murine fibroblast) cells
were maintained as described previously (40, 43). The
Kentucky A (KyA) strain of EHV-1 was propagated in L-M suspension
culture at a low multiplicity of infection (MOI) of 0.01 PFU per cell
and was assayed for infectivity by plaque titration (3, 4,
17).
Plasmids.
The generation of the effector constructs pSVIE,
pSVUL3, pCDR4, and pSVICP0K and the reporter constructs pIE-CAT,
pTK2-CAT, pIR5-CAT, and pgK-CAT has been described previously (2,
22, 40, 43, 47). These effector constructs express the EHV-1 IE
(pSVIE), EICP27 (pSVUL3), EICP22 (pCDR4), and EICP0 (pSVICP0K) proteins
under the control of either the simian virus 40 promoter (SVIE, SVUL3,
and SVICP0K) or the cytomegalovirus promoter (pCDR4). To construct
carboxy-terminal truncation mutants n163 and
n213, pSVICP0K was partially digested with
Ecl136II, and singly cut DNA fragments were purified by
using the Gene Clean kit (Bio 101, Vista, Calif.). The purified
fragments were ligated in the presence of an XbaI linker
(CTAGTCTAGACTAG; New England Biolabs, Beverly, Mass.) that
contains a nonsense codon in all three open reading frames
(6). To generate carboxy-terminal truncation mutants n227 and n325, pSVICP0K was partially digested
with HincII, and purified fragments were ligated as
described above. To create carboxy-terminal truncation mutants
n135, n141, and n282, pSVICP0K was
partially digested with AluI, and singly cut DNA fragments were ligated to the XbaI linker as described above. The
locations of the linkers were verified by restriction enzyme digestion
and agarose gel electrophoresis. The n135, n141,
n163, n213, n227, n282, and
n325 mutants express the first 135, 141, 163, 213, 227, 282, and 325 amino acids (aa) of the EICP0 protein, respectively. To
generate the d105 construct, the Sma3 clone (2) was digested with NcoI (nucleotide [nt] 572) and EcoRV (nt
1702), and the 1,130-bp fragment was filled in with Klenow fragment and
cloned into a SmaI-digested pSVSPORT1 vector (Life
Technologies, Gaithersburg, Md.). This clone expresses an
amino-terminal-truncated form of the EICP0 protein that lacks the first
105 aa.
The 
ACID (deletion of aa 71 to 84 [71-84]), NLS
(289-293), SRICH (210-217), RING8-46, RING19-30, and
DIEBS deletion mutant plasmids were generated via a "Quik Change"
site-directed mutagenesis kit from Stratagene (La Jolla, Calif.) that
is based on a Pfu polymerase mutagenesis protocol. To
generate the ACID mutant, PCRs were performed with the complementary
mutagenic primers ACID#1 and ACID#2 (5' GAA ACA AAG GTG AGC GTG GGG CAA
TTT TTG GCC GTG 3' and 5' CAC GGC CAA AAA TTG CCC CAC GCT CAC CTT TGT TTC 3', respectively), which delete bp 257 to 298 of pSVICP0K, corresponding to aa 71 to 84 of the EICP0 protein, upon PCR
amplification. An aliquot of this PCR product was digested with
DpnI, leaving only the amplified mutagenized plasmids, which
were then transformed into supercompetent XL-1 Blue Escherichia
coli cells. The presence of the desired mutation was initially
identified via restriction enzyme digestion and was confirmed by DNA
sequence analyses. The NLS, SRICH, RING19-30, RING8-46, and
DIEBS deletion mutant plasmids were generated essentially as described
above except that different mutagenic PCR primers were used. For the
NLS mutant, the primers used were NLS#1 and NLS#2 (5' GTC GGC GCA
GCG CCC AGC CCA GAA CCA AC 3' and 5' GTT GGT TCT GGG CTG GGC GCT GCG
CCG AC 3', respectively), which deleted bp 911 to 925 of pSVICP0K, corresponding to aa 289 to 293 of the EICP0 protein. For the
preparation of the SRICH mutant, the mutagenic primers used were
SRICH#1 and SRICH#2, which contained the sequences 5' GAG GGG TAG AAT ACA TTG ACG AGG AAG AAA CAG ACA GC 3' and 5' GCT GTC TGT TTC TTC CTC
GTC AAT GTA TTC TAC CCC TC 3', respectively. Amplification of pSVICP0K
with these primers would delete bp 674 to 694 of pSVICP0K, corresponding to aa 210 to 217 of the EICP0 protein. To prepare RING19-30, the mutagenic primers used were RING#3 and RING#4, which
contained the sequences 5' CTG GAG GAC CCC AGC AAC TAC GTG TGT ATT ACG
CGC TGG ATA 3' and 5' TAT CCA GCG CGT AAT ACA CAC GTA GTT GCT GGG GTC
CTC CAG 3', respectively. Amplification of pSVICP0K with these primers
would delete the base pairs of pSVICP0K corresponding to aa 19 to 30 of
the EICP0 protein. To generate RING8-46, in which EICP0 aa 8 to 46 were deleted, PCR primers RING#1 and RING#2 were used; they contained
the sequences 5' ATG GCA ACT GTT GCA GAG CGA AAA GTG CCG GTC GAA TCT
GTG 3' and 5' CAC AGA TTC GAC CGG CAC TTT TCG CTC TGC AAC AGT TGC CAT
3', respectively. The DIEBS mutant plasmid is devoid of a degenerate IE
binding site (ATCGc) located at bp 
12 to 8 relative to the EICP0
translation initiation site. This plasmid was generated with the
mutagenic primers IEBS#1 and IEBS#2, which contain the sequences 5' TCA TTT GGA AAC TCT TCC AAG CCA CCA TGG CAA CTG TTG C 3' and 5' GCA ACA GTT
GCC ATG GTG GCT TGG AAG AGT TTC CAA ATG A 3', respectively.
Because this PCR-based mutagenesis protocol depended on the
amplification of the entire plasmid, larger regions of the EICP0
gene
corresponding to the deletions were reinserted back into
the parental
pSVICP0K plasmid to ensure that the only mutagenized
region was the
desired one. To generate the
NLS clone that was
used in subsequent
transient transfection assays, the original
NLS clone (described
above) was digested with
NgoAIV and
BsmBI,
and
the 252-bp fragment was cloned into
NgoAIV- and
BsmBI-digested
pSVICP0K. To generate the
ACID, DIEBS,
RING19-30, and
RING8-46
clones later used in transient
transfection assays, the original
mutagenized clones (described above)
were digested with
EcoRI
and
SstII, and the
649-bp fragment from each mutant was cloned
into
EcoRI- and
SstII-digested pSVICP0K. To generate the
SRICH
clone for
use in transient transfection assays, the original mutagenized
SRICH
clone (described above) was digested with
SstII and
NgoAIV,
and the 225-bp fragment was cloned into
SstII- and
NgoAIV-digested
pSVICP0K. The
authenticity of these newly generated deletion mutant
clones was
confirmed by DNA sequence analysis of the cloned
fragments.
Transfection procedure and CAT assays.
Transient
transfections were performed by combining the appropriate amounts of
effector and reporter constructs in 500 µl of Eagle's minimal
essential medium (EMEM) and allowing this mixture to incubate at room
temperature. In a separate tube, 22 µl of Lipofectin reagent (Life
Technologies) was added to 1 ml of EMEM and allowed to incubate at room
temperature for 45 min for liposome formation. Following these
incubations, the plasmid DNA and Lipofectin were mixed, gently swirled,
and allowed to incubate for an additional 15 min at room temperature.
Finally, 1.5 ml of this mixture was added to each 60-mm dish of
approximately 4 × 106 L-M cells for a 5-h incubation
period at 37°C under 5% CO2. The cells were harvested at
62 h posttransfection, and CAT assays were performed as described
previously (2). Each CAT assay was independently repeated at
least three times, and within individual experiments each sample was
assayed in triplicate. Data were analyzed for statistical significance
by the Student t test.
Infection, metabolic labeling, and immunoprecipitations.
To
label the infected cell proteins with
[32P]orthophosphate, approximately 1.5 × 107 L-M cells were washed twice, placed in phosphate-free
EMEM, and infected with EHV-1 KyA at an MOI of 20 for 1.5 h. At
1.5 h postinfection, the cells were again washed and placed in
phosphate-free EMEM, and [32P]orthophosphate was added at
a concentration of 100 µCi/ml. Cells were harvested at 4, 5, 6, 7, and 8 h postinfection. Cells were lysed in 1 ml of
radioimmunoprecipitation (RIPA) buffer (150 mM NaCl, 50 mM Tris-HCl
[pH 8.0], 0.1% sodium dodecyl sulfate [SDS], 0.5% deoxycholate,
1.0% Nonidet P-40) containing protease inhibitors (aprotinin [50
µg/ml], leupeptin [50 µg/ml], and phenylmethylsulfonyl fluoride
[300 µg/ml]), passed through a 21-gauge needle three times, and
centrifuged, and the cell lysates were transferred to a fresh tube.
Equivalent volumes of sample per time point were used for the
immunoprecipitation reactions. The samples were precleared by the
addition of a 1:20 dilution of preimmune rabbit serum for 1 h at
4°C with rocking. Thirty-five microliters of protein A-agarose beads
(Sigma Chemical Company, St. Louis, Mo.) was added to the protein
extracts, which were incubated for 1 h at 4°C with rocking. The
beads were pelleted by centrifugation, and the precleared extract was
placed in a fresh microcentrifuge tube. These metabolically labeled
cell extracts were then subjected to immunoprecipitation at 4°C
overnight using 5 µl of TrpE-ICP0 antiserum (2).
Thirty-five microliters of protein A-Sepharose beads was added, and the
mixture was incubated overnight with rocking. The beads were pelleted by centrifugation and washed three times in RIPA buffer, and the proteins were eluted in Laemmli sample buffer (2% SDS, 10% glycerol, 5% 2-mercaptoethanol, 0.1% bromophenol blue, 62.5 mM Tris-HCl [pH
6.8]). Samples were analyzed by SDS-polyacrylamide gel electrophoresis (PAGE), and the proteins were visualized by autoradiography (3, 4).
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RESULTS |
The IE protein inhibits the ability of the EICP0 protein to
activate EHV-1 promoters.
Both the IE and EICP0 proteins are
potent trans-activators of EHV-1 promoters (2,
40). To assess whether these proteins function synergistically,
transient cotransfection analyses were performed with EHV-1 promoters
representing each kinetic class. As observed previously (Fig.
1A), the EICP0 protein is an activator of
the EHV-1 IE promoter and increased its expression approximately 3.1-fold above basal levels; the IE protein down-regulates its own
promoter, resulting in a 7-fold decrease from basal levels (2,
40). The presence of both the EICP0 and IE proteins resulted in a
level of trans-activation approximately equal to basal
levels, indicating that either the IE protein interferes with EICP0
function or EICP0 cannot completely overcome the ability of the IE
protein to autoregulate its own promoter. Both the IE and EICP0
proteins independently trans-activated the EHV-1 early
thymidine kinase (TK) promoter and increased expression from this
promoter approximately 4.7- and 6.9-fold, respectively (Fig. 1B).
However, when used together, they did not function synergistically.
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FIG. 1.
trans-Activation of representative EHV-1 IE,
early, 1 late, and 2 late promoters linked to the CAT reporter
gene by effector constructs expressing the IE and/or EICP0 proteins. (A
through D) L-M cells were transfected with each promoter-CAT reporter
construct and 0.3 pmol of either pSVIE and/or pSVICP0K. Transfected
cells were harvested, and CAT assays were performed as described
previously (2). Each transfection was performed at least in
triplicate, and the experiment was carried out independently at least
three times. Error bars, standard deviations. Shown is
trans-activation of the EHV-1 IE reporter construct
(pIE-CAT; 1.4 pmol) (A), the EHV-1 early (E) TK reporter construct
(pTK2-CAT; 1.4 pmol) (B), the EHV-1 1 late IR5 promoter (pIR5-CAT;
1.4 pmol) (C), and the EHV-1 2 late gK promoter (pgK-CAT; 2.0 pmol)
(D). (E) Dose-dependent trans-activation of the 1 IR5
promoter (pIR5-CAT; 1.4 pmol). The amount of each effector plasmid is
given along the x axis.
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The EICP0 protein activated expression of the
1 late IR5 promoter
approximately 40-fold (Fig.
1C), and, as previously reported,
the IE
protein did not activate this promoter (
40). The IE protein
significantly retarded the ability of the EICP0 protein to activate
the
IR5
1 late promoter, since CAT expression in the presence
of both
proteins was approximately 3.9-fold above basal levels.
A similar
effect was observed with the glycoprotein K (gK)
2
late promoter
(Fig.
1D). Interestingly, the IE protein also down-regulated
the gK
promoter, approximately 8-fold. Recent studies revealed
that the IE
protein binds near the transcription initiation site
of the gK
promoter, thereby repressing its transcription (
25).
A titration experiment using the IR5
1 late promoter was performed
to determine if the antagonism between EICP0 and IE proteins
is dose
dependent. As shown in Fig.
1E, the IE protein alone did
not activate
expression from this promoter, whereas 0.3 pmol of
the EICP0 plasmid
increased expression from this late promoter
59-fold. When any
combination of the IE and EICP0 effector constructs
was tested, the
levels of
trans-activation never approached that
obtained
when the EICP0 effector construct was transfected alone.
For example,
when 0.3 pmol of the IE effector construct was cotransfected
with 0.1 to 0.5 pmol of the EICP0 plasmid, increased expression
from the IR5
promoter ranged from 9- to 12-fold. When the amount
of the EICP0
plasmid transfected was held constant at 0.3 pmol,
the level of
activation varied from 20- to 4.7-fold depending
on the amount of the
IE plasmid cotransfected. At 0.1 pmol of
IE plasmid, the level of
activation was 20-fold, the highest observed.
When 0.5 pmol of the
pSVIE plasmid was cotransfected with the
EICP0 plasmid, the level of
activation decreased to 4.7-fold.
Therefore, increasing the amount of
the IE plasmid transfected
reduced the ability of the EICP0 protein to
activate the IR5
1
late promoter. These findings indicate that the
IE protein inhibits
the function of the EICP0 protein at all
concentrations of EICP0
plasmid tested and that the degree of
inhibition is dose
dependent.
A degenerate IE binding site (ATCGc) (S. K. Kim and D. J. O'Callaghan, unpublished data) is located in the EICP0 untranslated
region (bp
12 to
8 relative to the EICP0 translation initiation
site). To determine whether the ability of the IE protein to bind
to
this site could account for the IE-EICP0 antagonism, an EICP0
expression vector (DIEBS) that lacked this IE binding site was
generated. Both the wild-type EICP0 expression vector (SVICP0K)
and
DIEBS were able to independently activate the
1 late IR5
promoter,
15- and 13-fold, respectively (Fig.
2),
whereas the
IE protein did not activate this promoter. The IE protein,
however,
was able to inhibit the ability of DIEBS to activate the IR5
promoter,
and the level of inhibition was similar to that observed with
the wild-type SVICP0K construct (fourfold activation for SVICP0K;
threefold activation for DIEBS). These data suggest that a mechanism
other than the binding of the IE protein to this site in the EICP0
promoter accounts for the antagonistic relationship of these two
regulatory proteins.
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FIG. 2.
trans-Activation of the 1 late IR5
promoter by effector constructs expressing the IE and/or EICP0
proteins. L-M cells were transfected with 1.4 pmol of the pIR5-CAT
construct and 0.3 pmol of either SVICP0K, SVIE, DIEBS, or combinations
of these three effector constructs. Transfected cells were harvested,
and CAT assays were performed as described previously (2).
Each transfection was performed in triplicate, and the experiment was
carried out independently two times. Error bars, standard deviations.
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The EICP22 protein does not significantly enhance the ability of
the EICP0 protein to activate EHV-1 promoters.
To determine
whether the EICP0 and EICP22 proteins function synergistically, a
series of transient cotransfection analyses were performed with the IE,
early (TK), 1 late (IR5), and 2 late (gK) promoters (Fig.
3). As demonstrated in Fig. 3, the EICP22 protein was able to activate the IE, TK, IR5, and gK promoters only to
minimal levels. As reported previously (2), the EICP0 protein was a very powerful activator of EHV-1 promoters, resulting in
9.8-fold activation of the IE promoter, 71-fold activation of the TK
promoter, 26-fold activation of the 1 late IR5 promoter, and 26-fold
activation of the 2 late gK promoter (Fig. 3). The presence of both
the EICP22 and EICP0 proteins neither enhanced nor reduced expression
of the IE, TK, IR5, or gK promoters beyond the levels obtained with the
EICP0 protein alone, indicating that these two regulatory proteins do
not function synergistically or antagonistically on these promoters
(Fig. 3).
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FIG. 3.
trans-Activation of representative EHV-1 IE,
early, 1 late, and 2 late promoters linked to the CAT reporter
gene by effector constructs expressing the EICP22 and/or EICP0
proteins. L-M cells were transfected with each promoter-CAT reporter
construct and 0.3 pmol of either pCDR4 (EICP22 expression construct)
and/or pSVICP0K. Transfected cells were harvested, and CAT assays were
performed as described previously (2). Each transfection was
performed in triplicate, and the experiment was carried out
independently three times. Error bars, standard deviations. (A)
trans-Activation of the EHV-1 IE reporter construct
(pIE-CAT; 1.4 pmol); (B) trans-activation of the EHV-1 early
(E) TK reporter construct (TK2-CAT; 1.4 pmol); (C)
trans-activation of the EHV-1 1 late IR5 promoter
(pIR5-CAT; 1.4 pmol); (D) trans-activation of the EHV-1 2
late gK promoter (pgK-CAT; 2.0 pmol).
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The EHV-1 EICP0 and EICP27 proteins function synergistically to
activate early and 1 late promoters.
To address whether the
EICP27 and EICP0 proteins function together, cotransfection experiments
were performed with reporter CAT constructs representing all classes of
EHV-1 promoters. In these experiments, the EICP0 protein independently
activated the IE, TK, IR5, and gK promoters 11-, 9-, 13.5-, and
19-fold, respectively, whereas the EICP27 protein activated these
promoters only minimally (Fig. 4). No
synergy or antagonism between the EICP0 and EICP27 proteins was
observed in the case of either the IE or the gK promoter (Fig. 4A and
D). However, the EICP0 and the EICP27 proteins functioned synergistically in the case of both the TK and IR5 promoters (Fig. 4B
and C). As reported previously (42, 47), the IE and the EICP27 proteins function synergistically to enhance expression of both
the TK and IR5 promoters (Fig. 4B and C). Results from these analyses
indicate that the EICP27 protein is capable of enhancing the
trans-activation function of the IE protein as well as that
of the EICP0 protein with regard to expression from early and 1 late
promoters.
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FIG. 4.
trans-Activation of representative EHV-1 IE,
early, 1 late, and 2 late promoters linked to the CAT reporter
gene by effector constructs expressing the IE, EICP0, and/or EICP27
proteins. L-M cells were transfected with each promoter-CAT reporter
construct and 0.3 pmol of pSVIE, pSVICP0K, and/or pSVUL3 (EICP27
effector construct). Transfected cells were harvested, and CAT assays
were performed as described previously (2). Each
transfection was performed in triplicate, and the experiment was
carried out independently three times. Error bars, standard deviations.
(A) trans-Activation of the EHV-1 IE reporter construct
(pIE-CAT; 1.4 pmol); (B) trans-activation of the EHV-1 early
TK2 reporter construct (pTK2-CAT; 1.4 pmol); (C)
trans-activation of the EHV-1 1 late IR5 promoter
(pIR5-CAT; 1.4 pmol); (D) trans-activation of the EHV-1 2
late gK promoter (pgK-CAT; 2.0 pmol).
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Construction and characterization of EICP0 nonsense and deletion
mutant plasmids.
The EICP0 protein can be divided into five major
regions: (i) a RING finger motif (RING; aa 8 to 46), (ii) an acidic
region (ACID; aa 71 to 84), (iii) a serine-rich region (SRICH; aa 210 to 217), (iv) a putative nuclear localization signal (NLS; aa 289 to
293), and (v) a glutamine-rich region (GLU; aa 318 to 419) (Fig. 5 and
6). Our previous study indicated that the EICP0 proteins of the KyA
strain and the Ab4p strain differ in size due to a 113-aa in-frame
deletion in the latter (2) (Fig. 5 and 6). Both of these
EICP0 proteins activated EHV-1 promoter-CAT reporter constructs
identically, indicating that this 113-aa segment is not essential for
the trans-activation function (reference
2 and data not shown). By using the KyA EICP0
protein, a panel of 13 EICP0 nonsense and deletion mutant plasmids that
targeted these domains (RING, ACID, SRICH, NLS, and GLU) was
constructed (Fig. 5 and 6). The results of restriction enzyme analyses
of these mutants indicated that the desired mutation was obtained (data not shown). In addition, the authenticity of each deletion mutant clone
was verified by DNA sequence analyses (data not shown).
To confirm that each mutant clone expressed a protein of the expected
size, each mutant plasmid was in vitro transcribed and
translated, and
the resulting proteins were subjected to either
SDS-PAGE analyses
followed by autoradiography or Western blot
analyses with EICP0
antiserum (data not shown). The mutant proteins
expressed from every
construct were of the expected size with
the exception of the d105
protein, which lacks both the RING finger
and acidic regions and
migrated more rapidly than expected. Such
aberrant migration by a
RING-less herpes simplex virus type 1
(HSV-1) ICP0 protein was also
observed by Everett (
9). In addition,
every EICP0 mutant
protein was shown to be expressed in mouse
L-M cells and to be
detectable by Western blot analyses following
transfection with
plasmids that express each EICP0 mutant (data
not
shown).
The RING finger domain is critical for activation of EHV-1
promoters by the EICP0 protein.
The trans-activating
abilities of the EICP0 mutants were examined in transfection assays
using the reporter plasmids IE-CAT, TK-CAT (early), IR5-CAT (1
late), and gK-CAT (2 late). With the exception of the IR5 (1
late) promoter, the nonsense mutants exhibited a progressive loss of
function as more of the carboxy terminus of the protein was removed
(Fig. 5). Activation of the IR5 promoter
was severely inhibited by the loss of aa 283 to 419 (the
n282 mutant). Interestingly, this mutant protein
(n282) was able to activate the TK and gK promoters to
levels that were at or slightly above those with the wild-type protein.
Amino acids 326 to 419, which contain the glutamine-rich region, were
dispensable for EICP0 function, since the n325 mutant
exhibited levels of trans-activation equal to or, in some
instances, greater than wild-type levels (Fig. 5).
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|
FIG. 5.
Relative abilities of EICP0 nonsense mutants to
trans-activate EHV-1 IE, early, 1 late, and 2 late
promoters. The construction of each mutant was described in Materials
and Methods. L-M cells were transfected with each promoter-CAT reporter
construct (1.4 pmol of pIE-CAT, pTK2-CAT, or pIR5-CAT; 2.0 pmol of
pgK-CAT) and 0.3 pmol of each effector construct. Transfected cells
were harvested, and CAT assays were performed as described previously
(2). Each transfection was performed in triplicate in
individual experiments. Each experiment was carried out independently
at least three times. The relative activity of each nonsense mutant
compared to wild-type EICP0 on each class of promoters (IE, early, 1
late, and 2 late) is shown beside each mutant and is expressed as a
percentage of the wild-type value, which was set at 100%. The Ab4p and
KyA EICP0 proteins are from different EHV-1 strains and differ only by
the presence or absence (Kya DEL) of a 113-aa region. Both forms of
this protein function identically in CAT assays.
|
|
The RING finger (aa 8 to 46) and acidic region (aa 71 to 84) were
necessary but not sufficient for activation of the four
promoters
tested. The d105 construct, which lacks the first 105
aa, including the
RING finger and acidic regions, was impaired
in its ability to activate
transcription from all promoters (Fig.
6). Conversely, constructs that expressed
only the RING finger
and the acidic regions (such as constructs
n135 and
n141) were
not able to fully activate
any promoter tested (Fig.
5). Loss
of only the acidic region impaired
the ability of the mutant EICP0
protein to activate the early and
1
late promoters (Fig.
6),
suggesting that the RING finger is the region
most responsible
for
trans-activation activity.
Interestingly, deletion of the
acidic region did not adversely affect
the ability of the EICP0
protein to activate the IE and
2 promoters;
in fact, the levels
of activation were near wild-type levels or
enhanced (120 to 260%
of wild-type activity).
View larger version (37K):
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|
FIG. 6.
Relative abilities of EICP0 deletion mutants d105,
ACID, NLS, SRICH, RING19-39, and RING8-46 to
trans-activate representative EHV-1 promoters. The
construction of each mutant was described in Materials and Methods. L-M
cells were transfected with each promoter-CAT reporter construct (1.4 pmol of pIE-CAT, pTK2-CAT, or pIR5-CAT; 2.0 pmol of pgK-CAT) and 0.3 pmol of each effector construct. Transfected cells were harvested, and
CAT assays were performed as described previously (2). Each
transfection was performed in triplicate in individual experiments.
Each experiment was carried out independently at least three times.
Values obtained for the mutants are expressed as percentages of the
wild-type value, which was set at 100%.
|
|
To assess the role of the RING finger directly, mutants that lacked
either the entire RING finger motif (
RING8-46) or one-half
of the
RING finger motif (
RING19-30) were generated. In transient
transfection assays, both of these RING finger mutants were severely
impaired in the ability to activate all promoters (Fig.
6). These
data
indicate that the RING finger motif is critical for EICP0
function.
Deletion of a putative NLS located at aa 289 to 293 did not impair the
ability of the mutant protein to
trans-activate any
promoter
tested, suggesting that either this region is not the
nuclear
localization domain or the 50-kDa EICP0 protein is of
a size sufficient
to enter the nucleus without an NLS (Fig.
6).
The EICP0 protein is phosphorylated during EHV-1 infection.
The EICP0 protein may be phosphorylated at the serine-rich region (aa
210 to 217). Deletion of this region (SRICH) did not affect the
ability of the EICP0 protein to fully activate the IE, early, and 1
late promoters but reduced the ability of this mutant protein to
activate the 2 late promoter to only 27% of wild-type activity.
This finding suggests that the degree of phosphorylation of the EICP0
protein in infection may play an important role in its ability to
activate the 2 late class of promoters. To determine whether the
EICP0 protein was phosphorylated, L-M cells were infected with the
EHV-1 KyA strain in the presence of [32P]orthophosphate.
Lysates of mock-infected and infected cells were prepared at 4, 5, 6, 7, and 8 h postinfection and subjected to immunoprecipitation with
EICP0 antiserum. The EICP0 protein was phosphorylated by 4 h
postinfection (Fig. 7, lane 2), and only
one of the three forms (2) of the EICP0 protein was
phosphorylated. To date, the phosphorylated form of the EICP0 protein
has been detected only in infected cells (Fig. 7), since
[32P]orthophosphate-labeled EICP0 protein was not
detected in either EICP0-expressing cell lines or cells transiently
transfected with the SVICP0K construct (data not shown). These data
suggest that a viral protein may contribute to the modification of the
EICP0 protein and that the level of phosphorylation of the EICP0
protein may be important in its ability to activate the 2 late
promoters.
View larger version (97K):
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|
FIG. 7.
The EICP0 protein is phosphorylated during infection.
Mock-infected L-M cells (lane 1) and infected labeled L-M cells
harvested at 4, 5, 6, 7, and 8 h postinfection (lanes 2 to 6, respectively) were immunoprecipitated with anti-EICP0 antiserum
(2). Immunoprecipitations were analyzed by SDS-PAGE gel
analyses followed by autoradiography.
|
|
| |
DISCUSSION |
In this study, evidence is presented that the EICP0 and IE
proteins, the two most powerful EHV-1 trans-activators, do
not function synergistically. Instead, the IE protein, an essential EHV-1 regulatory protein, interferes with the ability of the EICP0 protein to activate EHV-1 promoters. The antagonism exhibited by the IE
and EICP0 proteins differs from the relationship of their counterparts
in HSV-1 and varicella-zoster virus (VZV). One well-characterized
feature of the HSV-1 ICP0 and ICP4 proteins (ICP4 is the HSV-1 homolog
of the EHV-1 IE protein) is their ability to function synergistically
(5, 10-13, 36). The VZV EICP0 protein equivalent, the ORF61
protein, can down-regulate the trans-activation functions of
the VZV IE (ORF62) and EICP27 (ORF4) proteins (34).
A possible mechanism for the antagonism observed between the IE and
EICP0 proteins is that the IE protein, a sequence-specific DNA binding
protein, may bind to an IE consensus binding site in the pSVICP0K
expression vector and thereby inhibit its transcription. Although such
a binding site is present in the pSVICP0K plasmid, gel shift analyses
indicate that the IE protein does not bind to this site (Kim and
O'Callaghan, unpublished data). The finding that the
trans-activation ability of the DIEBS EICP0 mutant is inhibited by the IE protein confirms that binding of the IE protein to
the EICP0 promoter does not account for the antagonism observed between
the EICP0 and IE proteins. A possible explanation for this antagonism
involves a physical interaction between the two proteins. Although
there is no evidence that these two EHV-1 proteins physically interact,
it is documented that HSV-1 ICP0 and ICP4 physically associate and that
the sequences responsible for synergy and physical interactions map to
the carboxy terminus of the HSV-1 ICP0 protein (45). The
n325 mutant, which lacks the carboxy terminus of the EICP0
protein, is a better trans-activator than the wild-type
EICP0 protein, tempting speculation that the IE protein interacts with
this region of the EICP0 protein and inhibits its function. Another
possibility to explain this antagonism is that both the IE and EICP0
proteins compete for cellular transcription factors. The HSV-1 ICP4
protein interacts with TFIIB and TFIID (39), and recent data
from our laboratory reveal that the IE protein interacts specifically
with TFIIB (unpublished data). The HSV-1 ICP0 protein interacts with
three cellular proteins, but none of these proteins is directly
involved in transcription (14, 23, 24, 31, 32). However, to
date there is no evidence that the EICP0 protein interacts with any
cellular protein.
Previous studies from our laboratory indicated that the EICP27 protein
is an early accessory regulatory protein capable of (i) independently
activating the EHV-1 IE promoter and minimally activating EHV-1 early
promoters, (ii) functioning synergistically with the IE protein to
up-regulate expression from early and 1 late promoters, and (iii)
functioning synergistically with the EICP22 protein to
trans-activate the IE promoter (22, 47). Here we
report that the EICP27 protein can also function synergistically with
the EICP0 protein to activate early and 1 late promoters. The
precise mechanism of EICP27 function is unknown at present, but it is
interesting that EICP27 synergy with the IE protein and its synergy
with the EICP0 protein involve a common set of EHV-1 promoters.
It should be noted that a trivial explanation for the findings
concerning the effects of the IE, EICP22, or EICP27 protein on the
transactivation activity of the EICP0 protein would be that these
regulatory proteins affect the level of the EICP0 protein. However,
Western blot analyses of cells cotransfected with plasmids that express
these other EHV-1 regulatory proteins showed that this was not the case
and that the level of the EICP0 protein was not affected by expression
of these other proteins (data not shown).
Mutational analyses of the EICP0 protein indicated that several regions
of this protein are important for its ability to
trans-activate; the most important region maps within the
amino-terminal 105 aa. This region includes a RING finger motif that
binds zinc, is conserved among all ICP0 homologs, and is also found in
a plethora of cellular proteins (reviewed in references
15 and 38). Mutational analyses of the VZV ORF61 and HSV-1 ICP0 proteins also indicated that the RING
finger of each protein was necessary for its function (8, 33). Recently, Lium and Silverstein (30) showed that
alteration of any of the cysteine or histidine residues in the
C3HC4 consensus RING finger domain abolished
the trans-activation ability of the HSV-1 ICP0 protein.
Evidence presented here shows that deletion of the entire RING finger
or a portion of the RING finger abrogated the ability of these mutant
EICP0 proteins to activate any EHV-1 promoter tested.
Stevenson et al. (44) mapped the NLS of the ORF61 protein of
VZV and predicted that the NLS of the EICP0 protein of EHV-1 is located
at aa 289 to 293 (RLRRR). Our results indicate that deletion of these 5 aa has no effect on the activation of any of the EHV-1 promoters
tested. It should be noted that the ORF61 protein comprises 467 aa and
may require an NLS for entry into the nucleus. In contrast, the EICP0
protein is smaller (419 aa) and may not require a specific domain to
mediate nuclear entry.
Interestingly, a serine-rich tract located at aa 210 to 217 is not
necessary for EICP0 activation of IE, early, or 1 late promoters but
is required for full activation of the 2 late gK promoter. This
finding suggests that the phosphorylation state of the EICP0 protein
may be important for the activation of 2 late promoters. In this
regard the EICP0 protein exists as three distinct species, only one of
which is the phosphorylated form (2). Phosphorylation of
EICP0 is not detected in cells transiently transfected with EICP0
expression constructs or in cell lines that constitutively express the
EICP0 protein. Thus, it is likely that modification of this regulatory
protein is mediated by an EHV-1 gene product.
The glutamine-rich region located between aa 318 and 419 is dispensable
for EICP0 function, since the n325 mutant, which lacks a
major portion of this region, still activated all EHV-1 promoters tested at wild-type or higher levels. The carboxy-terminal region of
the HSV-1 ICP0 protein was not required for ICP0 to independently transactivate HSV-1 promoters but was required for synergy and physical
association with the HSV-1 ICP4 protein (reviewed in reference
45). Studies are currently in progress to determine whether the IE and EICP0 proteins physically interact and, if so,
whether the carboxy-terminal portion of the EICP0 protein is involved
in mediating this physical association. Hopefully, these and additional
experiments will contribute more insight into the role of EICP0 in the
EHV-1 replication cycle. Our present understanding of EHV-1 gene
regulation indicates that the EICP0 protein plays a very important role
in the activation of late genes. However, the mechanism by which EICP0
can independently trans-activate EHV-1 promoters and the
mechanism by which the IE protein interferes with EICP0 function are
not understood and are important questions to be addressed.
| |
ACKNOWLEDGMENTS |
We thank Suzanne Zavecz for excellent technical assistance. We
thank P. Smith, A. Frampton, W. Derbigny, and R. Albrecht for critical
reading of the manuscript.
This investigation was supported by research grants from the National
Institutes of Health (AI-22001).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Microbiology and Immunology, Louisiana State University Health Sciences Center, 1501 Kings Highway, P.O. Box 33932, Shreveport, LA 71130-3932. Phone: (318) 675-5750. Fax: (318) 675-5764. E-mail:
DOCALL{at}LSUMC.EDU.
| |
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Journal of Virology, February 2000, p. 1200-1208, Vol. 74, No. 3
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
