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J. Biol. Chem., Vol. 277, Issue 46, 44292-44299, November 15, 2002
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From the Department of Microbiology and the Kaplan Comprehensive
Cancer Center, New York University School of Medicine,
New York, New York 10016
Received for publication, June 1, 2002, and in revised form, July 22, 2002
HCF-1 is a cellular protein required by VP16 to
activate the herpes simplex virus (HSV) immediate-early genes.
VP16 is a component of the viral tegument and, after release into the
cell, binds to HCF-1 and translocates to the nucleus to form a complex
with the POU domain protein Oct-1 and a VP16-responsive DNA sequence. This VP16-induced complex boosts transcription of the viral
immediate-early genes and initiates lytic replication. In uninfected
cells, HCF-1 functions as a coactivator for the cellular transcription
factors LZIP and GABP and also plays an essential role in cell
proliferation. VP16 and LZIP share a tetrapeptide HCF-binding motif
recognized by the Lytic replication in herpes simplex virus begins with the
expression of the five viral immediate-early
(IE)1 genes that encode
multifunctional regulatory proteins necessary for expression of the
early genes and creation of an optimal environment for viral
replication (reviewed in Ref. 1). Transcription of the IE genes is
stimulated by VP16, a component of virion tegument layer (for reviews
see Refs. 2-4). Biochemical and genetic analyses have shown that
transactivation by VP16 is dependent on HCF-1, a ubiquitous cellular
transcription factor (5-8). VP16 binds directly to HCF-1, and this
allows subsequent association with the cellular POU domain protein
Oct-1 and the VP16-responsive sequence found in each IE gene promoter
known as the TAATGARAT motif. Once assembled, the VP16-induced complex
directs high level IE gene transcription by virtue of the potent
activation domain in the C terminus of VP16 (9, 10). VP16 does not
possess its own nuclear localization signal (NLS) but instead relies on association of HCF-1, which contains a bipartite basic residue-rich NLS
in the C-terminal subunit (11, 12). Thus HCF-1 provides two functions
required by VP16, complex assembly and nuclear targeting.
Human HCF-1 is expressed in a wide range of tissue types, including all
of the cell lines tested (13-16). In most cells, HCF-1 is exclusively
nuclear and tightly associated with chromatin (17). The HCF-1
polypeptide is synthesized as a 2035-amino acid precursor that is
subsequently processed into two subunits through proteolytic cleavage
at six HCFPRO repeats located near the center of the precursor (18-21). The bulk of HCF-1 protein exists in the processed form, with the N- and C-terminal subunits tightly but noncovalently associated as a heterodimeric complex (12, 20). In addition to
sequences required for proteolytic processing and subunit association, HCF-1 contains several domains that mediate interactions with other
transcription factors. At the N terminus there are six kelch repeats
that fold into a six-blade In addition to its role in VP16-induced complex formation, HCF-1 is
required for cellular proliferation (30). Analysis of the hamster
tsBN67 cell line revealed a temperature-sensitive mutation in HCF-1
that results from a missense mutation in the To better understand the cellular function of HCF-1, we initiated a
screen to identify cellular interacting proteins. Here we describe
isolation of cDNAs from a human brain library, encoding a small
cellular polypeptide, termed HPIP, which binds to the Yeast Two-hybrid Screen--
The bait plasmid
pLexA-HCF-1N380 was constructed by subcloning a fragment
encoding the first 380 residues of human HCF-1 into the
polylinker of pLexA Northern Blotting--
Human multiple tissue and cell line
Northern blots (Clontech) were probed according to
the manufacturer's instructions using a 32P-labeled probe
corresponding to nucleotides 1-707 of the human HPIP cDNA.
Mammalian Expression Plasmids--
Sequences encoding
full-length human HPIP were PCR amplified from brain cDNA clone
46.2 using oligonucleotide primers that add an XbaI
(5'-GCTCTAGAATCCTGCAGCAGCCCTTGCAGCG-3') and a
BamHI site
(5'-GGATCCTCAGAGCTCCATTATGTCCCCAGC-3') to the 5'- and
3'-terminal ends of the HPIP cDNA, respectively. This fragment was
subsequently shuffled into mammalian expression plasmids
pCGFLAG2 and pEGFP-C2
(Clontech) generating N-terminal fusions with the FLAG epitope and green fluorescent protein (GFP), respectively. Site-directed mutagenesis was performed by QuikChangeTM
mutagenesis (Stratagene). Subsequent truncations were generated by PCR
and confirmed by DNA sequencing. The nuclear localization signal of
HCF-1 was amplified by PCR and subcloned into the unique XbaI site. The plasmids encoding HA-tagged
HCF-1N380 has been described previously (22). The
cytomegalovirus-driven expression plasmid encoding GFP-I Transfection and Coimmunoprecipitation--
Human 293T cells
were transfected with LipofectAMINE 2000 (Invitrogen), using 20 µl of
reagent/6-cm dish. The extracts were prepared after 24 h by
resuspending the cells in high salt buffer (420 mM KCl, 10 mM Tris-HCl, pH 7.9, 5% glycerol, 0.25% Nonidet P-40, 0.2 mM EDTA, 0.5 mM phenylmethylsulfonyl fluoride,
0.2 mM sodium vanadate, 50 µM sodium
fluoride, 1 mM dithiothreitol). Under these conditions, the
plasma membrane is ruptured, but the nuclear membrane is maintained,
although it becomes porous to soluble nuclear proteins (21). After
incubation for 20 min at 4 °C, extracted nuclei and other insoluble
debris were removed by centrifugation. For immunoprecipitations, 100 µl of the extract was incubated with 2.4 µl of HA-specific antibody
(12CA5)-coupled protein G-agarose beads (Roche Molecular Biochemicals)
at 4 °C for 1 h. The beads were washed three times in 1 ml of
wash buffer (200 mM KCl, 10 mM Tris-HCl, pH
7.9, 5% glycerol, 0.5 mM EDTA) before separation by
SDS-polyacrylamide gel electrophoresis. Immunoblotting was performed
with wet transfer and detected by enhanced chemiluminescence (SuperSignal; Pierce). The Green Fluorescence and Immunofluorescence Microscopy--
Cos-1
cells were seeded onto sterile coverslips in a 24-well plate and
transfected with 100 ng of expression plasmids encoding HPIP or
HCF-1N380 using LipofectAMINE 2000 (Invitrogen). After 24 h, the cells were fixed in 3.7% formaldehyde for 15 min,
washed three times in phosphate-buffered saline (PBS), quenched in 100 mM ammonium chloride, and then permeabilized with 0.1%
Triton X-100 diluted in PBS. After washing in PBS, the samples were
blocked with 10% fetal bovine serum and 0.25% saponin in PBS for 30 min at 37 °C. The samples were then incubated with Characterization of HPIP--
To identify cellular factors that
interact with the
The predicted HPIP polypeptide reveals limited similarity to other
characterized proteins; however, it does possess a number of
interesting features. The most notable is a potential HCF-binding motif
or HBM (DHPY, residues 76-79) located near the center of the
polypeptide (Fig. 1A) and is perfectly conserved in the
rodent sequences. This tetrapeptide motif is found in other HCF-1
interacting proteins, notably VP16 and LZIP, and is the primary
determinant for association with the HCF-1
Using commercially obtained filter sets, we performed Northern blot
analysis to examine the tissue distribution of HPIP mRNA (Fig.
1C). Two major transcripts of ~950 and 1100 nucleotides in
length were detected in poly(A)+ selected mRNA derived
from a variety of primary human tissues. In general, HPIP mRNA
appeared less abundant in cultured cell lines, although unambiguous
signals could be detected in mRNA derived from Raji and A549 cells.
These results are consistent with the analysis of expressed sequence
tags, which indicate a relatively broad distribution of HPIP mRNA expression.
The HBM Is Required for Specific Association with the HCF-1
To confirm the interaction between HPIP and the HCF-1
To confirm this observation, we asked whether the GFP-HPIP fusion was
capable of coimmunoprecipitating endogenous HCF-1 proteins (Fig.
2C). Extracts were prepared from 293T cells transiently transfected with plasmids encoding GFP (lane 1), GFP-HPIP
wild type (lane 2), and GFP-HPIP HBM KO (lane 3)
and immunoprecipitated using HPIP Shuttles between Cytoplasmic and Nuclear Compartments--
To
determine the subcellular localization of HPIP, we used fluorescence
microscopy to localize GFP-tagged versions of full-length HPIP in
transiently transfected Cos-1 cells (Fig.
3A). Both wild type GFP-HPIP
(panels a and c) and the naturally occurring
splice variant GFP-HPIPAS (panels b and
d) showed a similar distribution of fluorescence spread
throughout the cell with a modest increase in signal within the nucleus
compared with the cytoplasm. Fluorescence was excluded from the
nucleoli and cytoplasmic vacuoles. GFP alone showed a similar
widespread pattern, except that the nucleus was less clearly defined
(data not shown).
To investigate the possibility that HPIP actively cycles between
nuclear and cytoplasmic compartments, we treated GFP-HPIP expressing
Cos-1 cells with leptomycin B (LMB), a specific inhibitor of the
CRM1-mediated nuclear export pathway (34-37). This experiment is shown
in Fig. 3B. In the absence of LMB, GFP-HPIP was distributed throughout the cell (Fig. 3B, panel a); however,
in the presence of drug, GFP-HPIP accumulated in the nucleus as
discrete speckles with very little cytoplasmic fluorescence
(panel b). As controls, cells were transfected with
GFP-I HPIP Contains a Leucine-rich Nuclear Export Signal--
The
CRM1/exportin 1 protein functions by recognizing one or more nuclear
export signals (NESs) within the cargo protein (35, 38, 39). Typically,
each NES corresponds to a short sequence defined by a series of
appropriately spaced hydrophobic residues, most commonly leucines (40,
41). Examination of the HPIP sequence identified a leucine-rich region
(residues 89-119) toward the C terminus of the polypeptide (Fig.
1A). Within this sequence, we identified an imperfect match
(110IX3LXXLXL119)
to the NES consensus:
LX2-3LXXLXL. To determine
whether this leucine-rich region contained an NES, we generated a
series of C-terminal truncations (shown schematically in Fig.
4A) that were tested as GFP
fusions in transiently transfected Cos-1 cells (Fig. 4B).
Deletion of sequences beyond the leucine-rich region (GFP-HPIP
Mutation of the NES Reduces Export--
Having shown that deletion
of the HPIP C terminus leads to a dramatic nuclear accumulation of the
GFP fusion proteins, we focused on the putative NES located between
residues 110 and 120. Fig. 5C
shows an alignment of the putative NES with a selection of well
characterized examples from other proteins. From this alignment it is
clear that there is little sequence conservation of the variable
residues interspersed between the hydrophobic position. To verify that
the HPIP sequence is a bona fide NES, we changed two of the
key leucine residues (Leu117 and Leu119) to
alanine (HPIP NES mut). Analogous mutations have been shown to block
recognition by the CRM1 protein and nuclear export (40-43). The
mutations were generated in the context of full-length HPIP fused to
GFP. As shown in Fig. 5B, mutation of the NES led to a
partial accumulation in the nucleus. This was observed in 88% of
transfected cells. In the remaining 12% of cells the pattern of
fluorescence appeared indistinguishable from wild type GFP-HPIP. This
relocalization was less dramatic than with the C-terminal deletions but
still consistent with the presence of a leucine-rich NES. Conceivably
there are additional sequences in the C terminus that can function as
an export signal that are removed in HPIP
To determine whether the leucine-rich sequence was sufficient to
function as an export signal, we fused the 10 residues of the putative
NES sequence (110IPEALRLLRL119) to the
C-terminal subunit of HCF-1 (residues 1436-2035). This fragment
includes the HCF-1 NLS (residues 2014-2035) and is exclusively nuclear
(12). As summarized in Fig. 5C, addition of the HPIP NES led
to a substantial increase in cells with predominantly cytoplasmic
fluorescence. This result confirms that the minimal peptide is
sufficient to act as a NES when fused to a heterologous nuclear protein.
Elevated Expression of HPIP Leads to the Accumulation of HCF-1 in
the Cytoplasm--
The identification of a functional NES suggests
that HPIP might regulate HCF-1 function through association with the
We then asked whether the localization of endogenous HCF-1 could be
regulated by HPIP expression. As above, Cos-1 cells were transfected
with plasmids encoding GFP, GFP-HPIP, and the GFP-HPIP HBM KO mutant,
and the localization of endogenous HCF-1 protein was visualized
by indirect immunofluoresence using an HCF-1-specific antibody (rabbit
polyclonal Cytoplasmic Accumulation of HCF-1 Can Be Inhibited by LMB--
To
determine whether HCF-1 was being actively exported from the nucleus or
simply trapped in the cytoplasm following synthesis, we treated
transfected cells with LMB to disable CRM1-mediated export (Fig.
6C). As we had observed previously (Fig. 6A), a
significant fraction of GFP-NLS-HCF-1N380 was found in the
cytoplasm when cotransfected with FLAG-HPIP. This was observed in 85%
of transfected cells (panel a and b), whereas the
remaining 15% showed a more obvious localization to the nucleus (not
shown). Treatment with LMB resulted in all cells showing an exclusively
nuclear pattern for both GFP-NLS-HCF-1N380 and FLAG-HPIP
(panels c and d). This result implies that
GFP-NLS-HCF-1N380 is able to enter the nucleus following
synthesis but is then exported back to the cytoplasm through
association with HPIP.
We describe the identification of HPIP, a previously unknown
cellular polypeptide that interacts specifically with the The sequence of HPIP provides few clues to its function as an
HCF-1-binding protein. The only identifiable motifs are the HBM used
for recognition of the HCF-1 There is circumstantial evidence that the presence of HCF-1 in the
cytoplasm is likely to be important, if not essential, for lytic
replication by herpes simplex virus. During infection of permissive
cells, virions are disassembled at the plasma membrane, releasing the
viral capsid and tegument into the cytoplasm (45). The capsid is
thought to associate with microtubules and migrate to the nuclear pore
complex (46). Several tegument components, including VP16, function in
the nucleus and must therefore also be transported across the cytoplasm
and into the nucleus (47-49). O'Hare and co-workers (11) have shown
that VP16 does not possess its own nuclear localization signal and
instead relies on association of HCF-1 for translocation into the
nucleus. This seems paradoxical given the predominantly nuclear
location of HCF-1 in most cells and raises the intriguing question of
how VP16 interacts with HCF-1 after it is released from the virion. The
results presented here suggest that at least some molecules of HCF-1
actively shuttle between the nuclear and cytoplasmic compartments and
presumably it is the latter population that first encounters VP16 that
has been released from the virion tegument.
HCF-1 is expressed in almost all cells, and VP16 may have evolved to
exploit an active and ubiquitous transport mechanism. Although the
relative affinities of the HBMs from VP16 and HPIP have not been
compared, we anticipate the VP16 HBM to have the highest affinity for
the HCF-1 Antibodies against HPIP are not yet available, and there is currently
no information on the relative levels or subcellular localization of
HPIP in different cell types. Our Northern analysis and searches of the
expressed sequence tag data bases suggest a relatively broad
distribution of HPIP mRNA but does not address protein levels. In
principal, cells expressing highest levels of HPIP might show the
greatest proportion of cytoplasmic HCF-1. A case in point could be
sensory neurons in which HCF-1 is known to be largely cytoplasmic (16),
and it is tempting to speculate that HPIP contributes to the unique
distribution of HCF-1 in these cells. This attractive hypothesis can be
tested once appropriate reagents have been generated. Another
interesting issue is whether HCF-1 and HPIP remain in a complex in the
cytoplasm. Conceivably, HCF-1 is released from HPIP following export,
allowing it to return to the nucleus, possibly in conjunction with a
cargo protein such as VP16. Alternatively, the intact HCF-1-HPIP
complex may simply be reimported, and overall distribution would
reflect a balance between rates of export and import. If this is the
case, VP16 will need to disrupt the complex and gain access to the
HBM.
We thank Minoru Yoshida for the generous
gift of leptomycin B. Ranjan Sen, Michael Garabedian, Stavros
Giannakopoulos, and Ian Mohr provided helpful discussions, reagents
or advice. The manuscript was greatly improved by constructive comments
from Naoko Tanese.
*
This work was supported by National Science Foundation Grant
MCB-98-16856 and National Institutes of Health Grant GM61139.The costs of publication of this
article were defrayed in part by the
payment of page charges. The article
must therefore be hereby marked
"advertisement" in
accordance with 18 U.S.C. Section
1734 solely to indicate this fact.
The nucleotide sequence(s) reported in this paper has been submitted to the GenBankTM/EBI Data Bank with accession number(s) AY116892.
§
To whom correspondence should be addressed: Dept. of Microbiology,
NYU Medical Center, 550 First Ave., New York, NY 10016. Tel.:
212-263-0206; Fax: 212-263-8276; E-mail:
angus.wilson@med.nyu.edu.
Published, JBC Papers in Press, September 15, 2002, DOI 10.1074/jbc.M205440200
The abbreviations used are:
IE, immediate-early;
NES, nuclear export sequence;
NLS, nuclear localization sequence;
LMB, leptomycin B;
GFP, green fluorescence protein;
HA, hemagglutinin;
HBM, HCF-binding motif;
PBS, phosphate-buffered saline.
Interaction of HCF-1 with a Cellular Nuclear Export Factor*
,, and
ABSTRACT
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-propeller domain of HCF-1. Here we describe a new
cellular HCF-1 -propeller domain binding protein, termed HPIP, which
contains a functional HCF-binding motif and a leucine-rich nuclear
export sequence. We show that HPIP shuttles between the nucleus and
cytoplasm in a CRM1-dependent manner and that
overexpression of HPIP leads to accumulation of HCF-1 in the cytoplasm.
These data suggest that HPIP regulates HCF-1 activity by modulating its
subcellular localization. Furthermore, HPIP-mediated export may provide
the pool of cytoplasmic HCF-1 required for import of virion-derived VP16 into the nucleus.
INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-propeller (22-25). The -propeller domain is sufficient for interaction with VP16 and formation of the
VP16-induced complex. The HCF-1 -propeller also interacts with two
cellular bZIP proteins, LZIP and Zhangfei (15, 26). All three proteins
recognize the HCF-1 -propeller using a conserved tetrapeptide motif
known as the HCF-binding motif (HBM) (26, 27). The motif
((D/E)HXY) consists of an acidic residue (asparagine or
glutamic acid) followed by an invariant histidine, any residue (X), and then an invariant tyrosine. The HBM is an integral
part of the LZIP transactivation domain, and recruitment of HCF-1 is required for activation (28). In VP16, the HBM lies N-terminal to the
activation domain but is still required for transactivation (8,
29).
-propeller domain that
changes proline 134 to a serine. At the nonpermissive temperature,
tsBN67 cells undergo a stable arrest in G1/G0
but will reinitiate the cell cycle if returned to the permissive
temperature. The mutation prevents recognition of the HBM, and thus at
the restrictive temperature, transactivation by both VP16 and LZIP is
severely reduced (22, 28). This implies, but does not prove, that the
cell cycle arrest arises from a defect in cellular transcription.
-propeller
domain. HPIP contains a consensus HBM, which is essential for
association with HCF-1. HPIP also contains a leucine-rich nuclear
export signal and shuttles between the nucleus and cytoplasm using the
CRM1-mediated nuclear export pathway. These properties suggest that
HPIP functions as a chaperone for HCF-1, mediating export out of the
nucleus. Overexpression of HPIP leads to the accumulation of HCF-1 in
the cytoplasm, and this can be blocked using the CRM1 inhibitor
leptomycin B. Active shuttling of HCF-1 in and out of the nucleus
provides a mechanism for the nuclear import of VP16, whereupon it
initiates a cascade of lytic gene expression.
EXPERIMENTAL PROCEDURES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
PL (31). Yeast cells expressing
LexA-HCF-1N380 were then transformed with a human adult
brain cDNA library (Clontech) and scored for
lacZ expression by growth on medium containing 5-bromo-4-chloro-3-indolyl--D-galactopyranoside (X-gal).
A total of 11 positives were isolated from 6 × 106
independent transformants. Sequence analysis revealed that six of the
positives were derived from the same gene and were selected for further analysis.
B
(32)
was a kind gift from Dr. Ranjan Sen (Brandeis University).
HA (Roche Molecular Biochemicals) and
GFP (Molecular Probes) antibodies were diluted 1:5000 and 1:100,
respectively. Endogenous HCF-1 was detected using a rabbit polyclonal
antibody rHCF-H12 directed against epitopes in the C terminus
(21).
FLAG or
HCF-1 polyclonal antibody (rHCF (21), diluted 1:100) in blocking buffer for 1 h at 37 °C and washed three times with washing
buffer (7% fish gelatin and 0.025% saponin in PBS). The coverslips
were incubated with the secondary antibody (Texas Red -rabbit or
Texas Red -mouse; Molecular Probes) diluted 1:250 in blocking buffer for 1 h at 37 °C. The samples were washed, counterstained for 5 min with Hoechst 33528, washed, and fixed onto slides in fluorescence mounting medium (DAKO Corp.). Fluorescence was observed using a Zeiss
Axioplan microscope, and images were captured using Axioplan software
and exported into Adobe Photoshop 5.0 for further processing. In
addition, 100-150 cells from each sample (up to three coverslips) were
scored by visual inspection for nuclear or cytoplasmic accumulation of
the tagged proteins, and the cells shown in the photomicrographs were
chosen to illustrate the predominant patterns.
RESULTS
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-propeller domain of HCF-1, we performed a yeast
interaction screen using residues 1-380 (HCF-1N380) of
human HCF-1 fused to the LexA DNA-binding domain to screen a human
brain cDNA library. We obtained a number of clones that interacted
specifically with the bait. Six of these positive clones were
independently derived from the same gene and encode a previously
undescribed polypeptide that we will refer to as HPIP (HCF
-propeller interacting protein).
The predicted HPIP open reading frame encodes a polypeptide of 138 residues with a calculated molecular mass of 15.3 kDa (Fig.
1A). Searches of the expressed
sequence tag data base (dbEST) identified a number of additional
cDNA clones including those from mouse (AK013438) and rat
(AA944494). An alignment of the rodent sequences is given below the
human sequence in Fig. 1A and exhibits a relatively high
degree of conservation. We were unable to identify counterparts in
Drosophila or Caenorhabditis elegans. Searches of
the nearly complete human genome sequence revealed that the human gene
encoding HPIP is located on chromosome 16p13.3 (GenBankTM
Hs16_10709). From comparison of the genomic and cDNA sequences, we
predict a total of four exons (Fig. 1B). One of the six
clones isolated in the screen (clone 47.7) represents an alternatively spliced variant in which exon 2, encoding residues 33-51, is skipped, creating an internal deletion of 19 amino acids.
View larger version (31K):
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Fig. 1.
Characterization of HPIP cDNA
clones. A, predicted amino acid sequences of human
(h), mouse (m), and rat (r) HPIP.
Identical residues are indicated by a dot, whereas
introduced gaps are indicated with dashes. The HCF-binding
motif or HBM (DHPY) and leucine-rich region are boxed. In
human cells, alternative mRNA splicing removes 19 residues
(indicated as AS) that are not conserved in the rodent
counterparts. The nucleotide and predicted protein sequences reported
here have been deposited in the GenBankTM data base with
accession number AY116892. B, the deduced exon-intron
structure of human HPIP, indicating the origins of the alternative
splice variant (HPIPAS), which skips exon 2. C,
Northern blot analysis showing the distribution of HPIP mRNA
expression in a variety of human primary tissues and cells lines.
MW, molecular mass.
-propeller domain
(26-28). Toward the C terminus of HPIP, there is a
leucine-rich region (residues 90-119) that is also well conserved
between the three mammalian HPIP sequences. Secondary structure
analysis of HPIP predicts four -helices separated by unstructured
loops (indicated in Fig. 1A).
-Propeller HCF-1--
The presence of a candidate HBM near the
center of the predicted HPIP sequence suggests a mechanism for
association with the -propeller domain of HCF-1. Fig.
2A shows an alignment of the HPIP HBM and surrounding sequences with the corresponding peptides from
several VP16-like proteins encoded by herpesviruses as well as members
of the cellular bZIP family. The core tetrapeptide sequence from HPIP
(76DHPY79) is identical to that of the
varicella-zoster virus (HHV3) VP16 homologue (also known as the ORF10
protein), which is known to interact with HCF-1 (33). As noted
previously, there is almost no sequence conservation outside of the
core tetrapeptide; however, five of the eight sequences have a
hydrophobic residue (valine or isoleucine) at position 
3 relative to
the acidic residue of the HBM consensus. In HPIP this position
corresponds to the hydrophobic residue leucine. These similarities
support, but do not prove, the notion that HPIP contains a genuine
HBM.
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Fig. 2.
HPIP and HCF-1 associate in mammalian
cells. A, alignment of the HPIP sequence (black
background) with the HBM regions of VP16-like proteins from herpes
simplex virus-1 (HSV1), varicella-zoster virus
(VZV), bovine herpesvirus-1 (BHV1), and equine
herpesvirus-4 (EHV4) as well as the cellular HCF-1
interacting proteins human (hLZIP) and mouse LZIP
(mLZIP), Drosophila dCREB-A/BBF2
(dCrebA), and human Zhangfei (15, 26, 54). Identical
residues outside the core HBM are indicated with shading.
B, 293T cells were cotransfected with expression plasmids
encoding wild type or mutant versions of GFP-HPIP (3 µg) and
HA-tagged HCF-1N380 (2 µg). The extracts were prepared
and subject to coimmunoprecipitation using HA antibody-coupled
beads. Immunoprecipitates were resolved on a SDS-10% polyacrylamide
gel and immunoblotted using an GFP antibody (top panel).
To monitor protein expression, extracts were blotted directly using the
GFP (middle panel) or HA (bottom panel)
antibodies. Nonspecific cross-reacting bands are indicated with
asterisks. C, coimmunoprecipitation of endogenous
HCF-1. The extracts were prepared from transfected 293T cells
expressing GFP alone (lane 1), GFP-HPIP (lane 2),
and GFP-HPIP HBM KO mutant (lane 3). After
immunoprecipitation (IP) with GFP antibody beads, the
extracts were resolved by SDS-10% polyacrylamide gel electrophoresis
and probed with HCF-1 polyclonal sera (upper panel) or
GFP antibody (lower panel). The series of HCF-1
polypeptides detected by the rHCF-H12 antibody (21) are indicated
with bars. As reported previously, the higher molecular
mass HCF-1300 and HCF-1150 polypeptides
transfer poorly from 10% acrylamide gels and barely detected in this
exposure.
-propeller
domain, human 293T cells were cotransfected with expression plasmids
encoding HA-tagged HCF-1N380 and full-length HPIP fused to
the green fluorescence protein (GFP-HPIP). Protein extracts were
prepared and subjected to coimmunoprecipitation using HA antibody
beads. The precipitates were resolved on a SDS-polyacrylamide gel and
blotted using an GFP antibody (Fig. 2B).
Coimmunoprecipitation of GFP-HPIP was dependent on coexpression of
HA-tagged HCF-1N380 (compare lanes 2 and 3),
consistent with the interaction detected in yeast. To examine the role
of the putative HBM motif, we generated a substitution mutant in which
the critical aspartate, histidine, and tyrosine residues were changed
to alanine (Fig. 2A, GFP-HPIP HBM KO). Mutations of these
residues in VPI6 and LZIP are sufficient to disrupt the interaction
with HCF-1 (26-28). In contrast to wild type, the HBM mutant failed to
coimmunoprecipitate with wild type HCF-1N380 (lane
4), indicating that this is a bona fide HBM sequence. Lastly, we tested the alternative splice variant
(GFP-HPIPAS), which lacks 19 residues on the N-terminal
side of the HBM (Fig. 1A). GFP-HPIPAS
polypeptides were recovered with similar efficiency to GFP-HPIP
(lane 5), consistent with its identification of both variants in the yeast two-hybrid screen. These results show that HCF-1
and HPIP can form a complex in mammalian cells and that this
interaction is dependent on the HBM sequence in HPIP.
GFP-coupled beads. Precipitated
proteins were resolved on a SDS-10% polyacrylamide gel and probed with
antibodies to HCF-1 (upper panel) or GFP (lower
panel). Endogenous HCF-1 was readily detected in the sample
expressing wild type GFP-HPIP (lane 2). Significantly less
HCF-1 was recovered using the HBM mutant (lane 2) and was
similar to the background level detected with GFP alone (lane
1). This result indicates that exogenously expressed GFP-HPIP
associates with the endogenous HCF-1 protein in an
HBM-dependent manner.
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Fig. 3.
HPIP shuttles between the nucleus and the
cytoplasm. A, Cos-1 cells were transfected with
expression plasmids (100 ng) encoding GFP-HPIP (panels a and
c) and GFP-HPIPAS (panels b and
d). The nuclei were counterstained with Hoechst dye 33258 (panels c and d). B, nuclear export of
HPIP can be inhibited by LMB. Cos-1 cells expressing GFP-HPIP,
GFP-I B, or GFP alone were seeded in duplicate, and 24 h
post-transfection one set of samples was treated for 1 h with 20 ng/ml leptomycin B (+ LMB) or with vehicle alone ( LMB) and fixed for microscopy. The nuclei were counterstained with
Hoechst 33258. C, quantitation of the experiment shown in
B. At least 100 cells were scored for nuclear
(N), cytoplasmic (C), and nuclear/cytoplasmic
(N+C) distribution. The values are plotted as percentages of
the total number of transfected cells examined.
B (panels c and d) and GFP alone
(panels e and f). As previously reported,
GFP-IB showed a dramatic redistribution from the cytoplasm to the
nucleus following exposure to LMB (32). GFP alone was found in both the
nucleus and the cytoplasm, and this distribution was unaltered by drug treatment. Fig. 3C shows quantitation of this data. At least
100 cells from each sample were scored for GFP signal in the nucleus (N), cytoplasm (C), or both compartments
(N+C) and plotted as percentages of the total. The data
clearly show that relocalization of GFP-HPIP in response to LMB
treatment occurred in the majority of cells. Taken together, these
results argue that GFP-HPIP is in a state of dynamic exchange between
the cytoplasmic and nuclear compartments and that the CRM-1-mediated
export pathway mediates its export from the nucleus into the cytoplasm.
121-138, panel b) did not alter the distribution from the wild type fusion protein, whereas the next deletion (GFP-HPIP 109-138, panel c), which removed the putative NES, led
to a striking accumulation in the nucleus. 94% of transfected cells
showed predominantly nuclear fluorescence, whereas the remainder showed
fluorescence in both the nucleus and the cytoplasm. Moreover, this
nuclear localization was maintained (96% of transfected cells) when
the entire leucine-rich region (GFP-HPIP 90-138, panel
d) was removed. Immunoblotting of parallel transfections confirmed
that the fusion proteins were of the expected size and expressed at
similar levels (data not shown). These results indicate that HPIP
contains a functional leucine-rich NES located between residues
108-120, the region that incorporates the near-consensus NES.
View larger version (28K):
[in a new window]
Fig. 4.
The leucine-rich region is required for
nuclear export. A, schematic showing HPIP truncations.
Cytoplasmic (+) versus nuclear ( ) accumulation is
indicated. B, representative Cos-1 cells transfected with
plasmids (100 ng) encoding GFP-HPIP WT (panels a and
e), GFP-HPIP 121-138 (panels b and
f), GFP-HPIP 109-138 (panels c and
g), or GFP-HPIP 90-138 (panels d and
h). After incubation for 24 h, the cells were fixed and
analyzed. The nuclei were counterstained with Hoechst 33258 (panels e-h).
109-138, which shows a
more overt nuclear accumulation (Fig. 4B).
View larger version (34K):
[in a new window]
Fig. 5.
Identification of the HPIP nuclear export
signal. A, alignment of the HPIP sequence (residues
110-119) with known NES from -actin (55), c-abl (56),
IB (57, 58), and HIV Rev (40, 59). The two-leucine residues in
HPIP (Leu117 and Leu119) targeted for alanine
substitution mutagenesis (HPIP NES mut) are indicated. B,
Cos-1 cells were transfected with plasmids (100 ng) encoding GFP-HPIP
or GFP-HPIP NES mut. C, quantitation of nuclear
versus cytoplasmic staining (expressed as a percentage) of
Cos-1 cells transfected with plasmids encoding GFP-HCF-1C
(n = 112) or GFP-NES-HCF-1C
(n = 107).
-propeller domain and subsequent export into the cytoplasm. To
address this, we cotransfected Cos-1 cells with a plasmid encoding the
HCF-1 -propeller domain fused to GFP (GFP-NLS-HCF-1N380)
and FLAG-tagged versions of wild type and HBM mutant versions of HPIP
(Fig. 6A). The GFP-HCF-1
fusion includes a single copy of the HCF-1 NLS to ensure that it is
imported into the nucleus (panel c). Coexpression with
FLAG-HPIP leads to a significant accumulation of
GFP-NLS-HCF-1N380 protein in the cytoplasm (panel
d), paralleling the diffuse fluorescence of FLAG-HPIP (panel
a). This relocalization of GFP fluorescence was not seen using the
mutant version of HPIP (panel e), even though FLAG-HPIP HBM
KO shows a similar localization to HPIP wild type (compare panels
a and b), indicating that direct association is
required for relocalization of GFP-HCF-1.
View larger version (24K):
[in a new window]
Fig. 6.
Expression of wild type HPIP promotes
relocalization of HCF-1 to the cytoplasm. A, Cos-1
cells were transfected with plasmids (100 ng) expressing
GFP-NLS-HCF-1N380 alone (panels c and
f) or together with plasmids encoding FLAG-tagged HPIP WT
(panels a, d, and g) or HPIP HBM KO
(panels b, e, and h). After 24 h,
the cells were fixed and probed using FLAG primary antibody followed
by a mouse IgG secondary antibody conjugated to Texas Red. The cells
were stained with Hoechst dye to visualize the nuclei (panels
f-h). B, as in A except that cells were
transfected with plasmids encoding GFP alone (panels a,
d, and g), GFP-HPIP WT (panels b,
e, and h), and GFP-HPIP HBM KO (panels
c, f, and i) and probed with an antibody
against HCF-1 (panels a-c) to detect the endogenous HCF-1
protein. GFP (panels d-f) and DNA (panels g-i)
were visualized by fluorescence. C, cytoplasmic accumulation
of HCF-1 is inhibited by leptomycin B. Cos-1 cells were transfected
with plasmids (100 ng) encoding GFP-NLS-HCF-1N380 and
FLAG-tagged HPIP WT, reseeded in duplicate, and 24 h
post-transfection treated for 1 h with vehicle alone
( LMB, panels a and b) or with
20 ng/ml leptomycin B (+ LMB, panels c and
d).
rHCF) (21). Transfected cells were identified by green
fluorescence. In cells expressing GFP alone, HCF-1 staining was
restricted to the nucleus (Fig. 6B, panel
a) in 100% of transfected cells. In marked contrast, expression
of GFP-HPIP led to a significant accumulation of HCF-1 protein in the
cytoplasm, seen in at least 70% of transfected cells and paralleling the diffuse fluorescence of GFP-HPIP (panels b and
e). This redistribution was not observed with the GFP-HPIP
HBM KO mutant, indicating that direct physical association is required
(panel c). This result shows that ectopic expression of HPIP
is capable of redirecting HCF-1 into the cytoplasm.
DISCUSSION
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES
-propeller domain of HCF-1. When expressed by transient transfection in cultured cells, GFP-tagged HPIP is found in both the cytoplasmic and nuclear compartments of the cell, and treatment with leptomycin B, an inhibitor
of the CRM1 export receptor, leads to a rapid accumulation in the
nucleus. These observations argue that the localization of HPIP is
dynamic and that HPIP shuttles in and out of the nucleus. To this end,
we identified a leucine-rich NES between residues 110 and 119 and show
that it is a key determinant for nuclear export. The HPIP NES resembles
canonical NESs with respect to the distribution of hydrophobic residues
and is therefore likely to function through direct interaction with the
CRM1 protein. Although leucine is most common at these positions,
several known CRM-binding sites utilize isoleucine and/or valine in
place of one or more leucines (40, 44). Deletion and point mutagenesis of the HPIP NES leads to nuclear accumulation of GFP-HPIP, reminiscent of LMB treatment, and we also show that this sequence is sufficient for
cytoplasmic localization of a nuclear protein.
-propeller and the NES, which mediates
nuclear export. This leads to the hypothesis that HPIP functions as a
shuttle factor that regulates HCF-1 localization, and this scenario is
shown schematically in Fig. 7. Two
observations support the idea that the accumulation of cytoplasmic
HCF-1 reflects nuclear export rather than some form of trapping or
sequestration. Firstly, ectopically expressed GFP-HPIP was able to
relocalize endogenous HCF-1 (Fig. 6B) as well as coexpressed
FLAG-HCF-1 (Fig. 6A). Because endogenous HCF-1 is presumably
already nuclear when HPIP is first expressed, HPIP must therefore first
enter the nucleus before it can redirect HCF-1. In a similar vein, we
show that LMB treatment inhibits the cytoplasmic accumulation of
GFP-NLS-HCF-1N380, again arguing that HPIP must first enter
the nucleus before it can export HCF-1 (Fig. 6C).
View larger version (26K):
[in a new window]
Fig. 7.
Model for HPIP-mediated nucleocytoplasmic
shuttling of HCF-1. Step 1, nuclear HCF-1 is exported
to the cytoplasm through association with HPIP, which interacts with
the N-terminal -propeller domain (HCF-1N), which
recognizes the HPIP HBM. The CRM-1 export protein (not illustrated)
recognizes the NES in HPIP. Step 2, HCF-1 may dissociate
from HPIP and return to the nucleus or return as complex with HPIP.
Step 3, in herpes simplex virus-infected cells, VP16 is
released into the cytosol together with other tegument components. The
HCF-1 -propeller domain interacts with the high affinity HBM of
VP16, and the resulting complex is transported through the nuclear
pore. Nuclear import of HCF-1 is mediated by its C-terminal NLS, which
is recognized by the importin complex (11, 12). Once in the
nucleoplasm, VP16, still complexed to HCF-1, can further associate with
Oct-1 and the TAATGARAT sequence found in the viral immediate-early
gene promoters. The resulting VP16-induced complex activates
transcription by way of the potent C-terminal activation of VP16.
-propeller. Certainly, in our hands VP16 can be
coimmunoprecipitated from transfected extracts more readily than HPIP,
consistent with a more stable association (data not shown). A
difference in affinity would allow the small number of VP16 molecules
released by a virion (~1000 molecules/virion) to efficiently
commandeer the available pool of cytoplasmic HCF-1, thereby ensuring
rapid translocation to the nucleus and activation of the viral IE
genes. In contrast to VP16, LZIP is probably not dependent on HCF-1 for
nuclear localization. LZIP contains a short membrane-spanning sequence
and is tethered to the endoplasmic reticulum (50). In response to
appropriate stimuli, LZIP is cleaved between the bZIP domain and
membrane tether, allowing the N terminus containing the activation and
basic zipper domains to translocate to the nucleus. As is the case with
other bZIP proteins, the basic region is probably sufficient for
nuclear localization (51-53). Interestingly, mutation of the HBM does
not prevent nuclear localization by HPIP (Fig. 6, A and
B). The sequence is devoid of clustered basic amino acids
that might serve as a NLS, and it is possible that HPIP associates with
additional nuclear proteins; this could be addressed by further
mutagenesis in the context of the disrupted HBM.
ACKNOWLEDGEMENTS
FOOTNOTES
Supported by the New York University School of Medicine Office of
Minority and Multicultural Affairs Summer Research Program.
ABBREVIATIONS
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TOP
ABSTRACT
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EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
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