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Journal of Virology, April 2001, p. 3250-3258, Vol. 75, No. 7
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.7.3250-3258.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Kaposi's Sarcoma-Associated Herpesvirus
Latency-Associated Nuclear Antigen 1 Mediates Episome Persistence
through cis-Acting Terminal Repeat (TR) Sequence and
Specifically Binds TR DNA
Mary E.
Ballestas and
Kenneth M.
Kaye*
Department of Medicine, Channing Laboratory,
Brigham and Women's Hospital, Harvard Medical School, Boston,
Massachusetts 02115
Received 25 August 2000/Accepted 3 January 2001
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ABSTRACT |
Kaposi's sarcoma (KS)-associated herpesvirus (KSHV) (also known as
human herpesvirus 8) latently infects KS tumors, primary effusion
lymphomas (PELs), and PEL cell lines. In latently infected cells, KSHV
DNA is maintained as circularized, extrachromosomal episomes. To
persist in proliferating cells, KSHV episomes must replicate and
efficiently segregate to progeny nuclei. In uninfected B-lymphoblastoid
cells, KSHV latency-associated nuclear antigen (LANA1) is necessary and
sufficient for persistence of artificial episomes containing specific
KSHV DNA. In previous work, the cis-acting sequence
required for episome persistence contained KSHV terminal-repeat (TR)
DNA and unique KSHV sequence. We now show that cis-acting KSHV TR DNA is necessary and sufficient for LANA1-mediated episome persistence. Furthermore, LANA1 binds TR DNA in mobility shift assays
and a 20-nucleotide LANA1 binding sequence has been identified. Since
LANA1 colocalizes with KSHV episomes along metaphase chromosomes, these
results are consistent with a model in which LANA1 may bridge TR DNA to
chromosomes during mitosis to efficiently segregate KSHV episomes to
progeny nuclei.
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INTRODUCTION |
Kaposi's sarcoma (KS)-associated
herpesvirus (KSHV) or human herpesvirus 8 is a gamma-2 herpesvirus
tightly linked to KS, primary effusion lymphoma (PEL), and multicentric
Castleman's disease, an aggressive lymphoproliferative
disorder (8, 9, 35, 47). KSHV infection in tumors and PEL
cell lines is predominantly latent. Latently infected cells have
multiple copies of extrachromosomal, circularized KSHV DNA (episomes)
(8, 13). To persist in proliferating cells, viral episomes
must first replicate and then segregate to progeny cells.
The latency-associated nuclear antigen (LANA1), encoded by KSHV open
reading frame 73, is one of a limited number of KSHV genes expressed
during latent infection (23, 24, 40). Confocal microscopy
using immunofluorescence and fluorescent in situ hybridization demonstrated that LANA1 colocalized with KSHV episomes in PEL cell
nuclei in interphase and along mitotic chromosomes (4, 12,
22-24, 48). Furthermore, in KSHV-uninfected lymphoblastoid cells, LANA1 mediates extrachromosomal persistence of artificial KSHV
episomes containing specific KSHV DNA (4). The KSHV Z6 cosmid, which includes KSHV terminal-repeat (TR) elements and the left
end of the KSHV genome, persisted as an episome in LANA1-expressing cells. In contrast, the Z8 cosmid, which contains sequence from near
the center of the KSHV genome, did not persist as an episome in
LANA1-expressing cells. Further, DNA containing the left end of Z6, but
not other Z6 segments, persisted as episomes in LANA1-expressing cells
(4, 43). Here we show that KSHV TR sequence is necessary and sufficient for LANA1-mediated episome persistence.
The ability of LANA1 to bind to TR DNA was also investigated since such
an interaction would be compatible with a role in episome maintenance.
Consistent with this possibility, LANA1 bound a segment of Z6 DNA which
includes the TR elements (12). Both the Epstein-Barr
virus (EBV) nuclear antigen 1 (EBNA1) and bovine papillomavirus E2
protein directly bind DNA and are hypothesized to tether cognate viral
DNA to chromosomes in order to mediate episome segregation to progeny
cells (5, 21, 30, 41, 46, 50, 52). For instance, EBNA1
binds to multiple sites within a cis-acting 1.8-kb EBV DNA
sequence termed origin of plasmid replication (oriP) to mediate episome
persistence (6, 41, 50, 52). Here we define a
20-nucleotide LANA1 binding site corresponding to nt 603 to 622 of the
KSHV TR (43). Since LANA1 colocalizes with KSHV episomes
along mitotic chromosomes and binds TR DNA, these results are
consistent with a model in which LANA1 directly binds KSHV episomes to
mediate episome persistence.
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MATERIALS AND METHODS |
Plasmids.
pRepCK has the sequence between ClaI
and KpnI of pRep9 (Invitrogen) deleted. Plasmid Z6-BE
contains the BglII-EcoRI fragment from the Z6-13
plasmid and has about eight copies of the TR unit and unique KSHV
sequence cloned into the BamHI-XhoI sites of the pRepCK vector (4). Z6-BE was digested with
NotI, and the 0.8- and ~0.6-kb KSHV DNA fragments were
purified and ligated into the NotI site of the pRepCK vector
to generate Z6-3TRA, Z6-2TR, Z6-1TR, and Z6-A. Z6-3TRA contains three
copies of the 0.8-kb TR unit and one copy of the 0.6-kb sequence.
Z6-2TR and Z6-1TR contain two copies and one copy, respectively, of the
0.8-kb TR unit. Z6-A contains one copy of the 0.6-kb KSHV DNA (termed
A), which was sequenced at a core facility by automated sequencing.
Selection of G418-resistant cells and Gardella gel analysis.
BJAB (KSHV-uninfected) B-lymphoblastoid cells or hygromycin (200 U/ml)
(Calbiochem)-resistant BJAB cells stably expressing FLAG epitope-tagged
LANA1 (BJAB/F-LANA1) (4) were transfected in 400 µl at
200V and 960 µF in a 0.4-cm-gap cuvette using a Bio-Rad Electroporator with Z6-BE, Z6-3TRA, Z6-2TR, Z6-1TR, or Z6-A. After 48 h, the cells were plated in 96-well microtiter plates (1,000 cells/well) in medium containing G418 (600 µg/ml) (Gibco). G418 resistance is conferred by the plasmid vector. After selection of
G418-resistant cell lines, Gardella gel analysis was performed by in
situ lysis of cells in gel-loading wells with pronase and sodium
dodecyl sulfate and electrophoresis in 1× Tris-borate-EDTA (TBE)
(17). DNA was transferred to a nylon membrane, and KSHV DNA was detected by Southern blot analysis using a
32P-labeled TR probe. Signal was captured with a Molecular
Dynamics PhosphorImager and analyzed with ImageQuant software.
DNA binding assay.
The 535-bp
NotI-AscI and 266-bp
NotI-AscI TR fragments were gel purified after
digestion of the Z6-2TR plasmid. After digestion of the 535-bp fragment
with AvaII, the 297-bp NotI-AvaII
fragment was isolated. The 535-bp fragment was also digested with
Sau3A, and the 370-bp fragment was gel purified. Fragments
were 32P radiolabeled by Klenow fill-in. Probes were
purified on a Sepharose G-50 column (Stratagene).
FLAG epitope-tagged LANA1 (F-LANA1) (4) and control immune
precipitates were assayed for the ability to bind radiolabeled TR DNA.
BJAB cells (2 × 107) stably expressing F-LANA1
(BJAB/F-LANA1 cells [4]) were lysed in lysis buffer (50 mM Tris [pH 7.5], 150 mM NaCl, 1% NP-40, 2 mM EDTA, 25 µg of
aprotinin per ml, 25 µg of leupeptin per ml, 1 mM
phenylmethylsulfonyl fluoride). Cell lysates were precleared with
protein G beads at 4°C for 1 h and incubated at 4°C for 2 h with M2 anti-FLAG monoclonal antibody-conjugated beads (Sigma) or
isotype-matched control antibody bound to protein G beads. The beads
were washed twice in lysis buffer and then washed three times in 1×
binding buffer (25 mM Tris [pH 7.5], 100 mM KCl, 5 mM EDTA, 10 mM
MgCl2, 0.1% NP-40, 5% glycerol, 0.1 mM dithiothreitol). Radiolabeled probe was incubated with the beads and 2 µg of poly (dI-dC) in 1× binding buffer for 30 min at room temperature. The beads
were then washed five times with 1× binding buffer, and bound DNA was
eluted from the beads at 95°C for 5 min with TE containing 0.1%
sodium dodecyl sulfate. Eluted DNA fragments were detected by
autoradiography after resolution on a nondenaturing 5% polyacrylamide
gel. The signal was captured with a PhosphorImager and analyzed with
ImageQuant software. Western blotting detected F-LANA1 only in M2 immunoprecipitates.
EMSA.
Oligonucleotides with 5'-GATC overhangs were annealed
and 32P radiolabeled by Klenow fill-in. For
electrophoretic mobility shift assays (EMSAs), in
vitro-translated F-LANA1 (3 µl of the reaction mixture) (TNT coupled
reticulocyte lysate systems [Promega]) was incubated in 1× reaction
buffer [20 mM Tris (pH 7.5), 10% glycerol, 50 mM KCl, 0.1 mM
dithiothreitol, 10 mM MgCl2, 1 mM EDTA, 1 µg (experiments
in Fig. 5 and 6A and B) or 20 µg (experiments in Fig. 6C and 7) of
poly(dI-dC) per ml] with 50,000 cpm of probe in 20 µl for 30 min at
room temperature with or without excess unlabeled competitor
oligonucleotides. For supershift assays, M2 or an irrelevant, murine
isotype matched control antibody (Southern Biotechnology Associates)
was added to the incubation mixture for 15 min prior to the addition of
radiolabeled probe. Bound and unbound probes were resolved by
electrophoresis in 3.5% nondenaturing polyacrylamide gels in 1× TBE.
The gels were dried, and the signal was detected by autoradiography.
Nuclear extracts were made by modified Dignam method (3).
For supershift assays with nuclear extracts, a rat monoclonal antibody
to LANA1 (ABI Biotechnology) or an irrelevant rat immunoglobulin G
control antibody (Southern Biotechnology Associates) was used.
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RESULTS |
LANA1 mediates efficient persistence of DNA containing the KSHV TR
sequence.
Experiments were performed to localize the
cis-acting sequence upon which LANA1 acts to mediate
episome persistence. Previous work demonstrated that LANA1
mediated the episome persistence of Z6, Z6-13, and Z6-3TRA but not Z6-7
and Z6-11 (Fig. 1) (4). Since Z6-3TRA contains only TR elements and ~0.6 kb of KSHV sequence from the far left end of Z6 (termed A) (Fig. 1), either the TR elements
or A is critical for LANA1-mediated episome persistence. Sequencing of
the ~0.6-kb A segment demonstrated that it is composed of KSHV nt
74931 to 75144 fused to a partial TR. The 5' end of the partial TR
sequence is TR nt 801, which is fused to TR nt 1 to 322, which
are in turn fused to TR nt 348 to 383 (43). (In
contrast to other reported KSHV TR sequences, A has GA in place of CC
at TR at 351 and 352 [28, 38, 43].) nt 74931 to 75144 in
A result from an insertion of this unique sequence into the BC-1 TRs
(41). Plasmids were generated to assay TR and A for
LANA1-mediated episome persistence. Z6-2TR and Z6-1TR contain two and
one TR element, respectively. Z6-A contains the ~0.6-kb A element
(Fig. 1).
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FIG. 1.
Schematic diagram of KSHV DNAs assayed for episome
persistence. Approximate KSHV genome coordinates (in kilobases) are
shown for Z6 (43). Vertical lines separate the ~0.8-kb
TR units. The diagrams are not drawn to scale. Episome persistence in
LANA1-expressing cells is indicated by +, and lack of episome
persistence is indicated by  . Z6, Z6-13, Z6-7, and Z6-11 were assayed
in earlier experiments for episome persistence (4). The
asterisk indicates that initial G418-resistant outgrowth of
BJAB/F-LANA1 cells transfected with Z6-1TR was slower than after
transfection of BJAB/F-LANA1 cells with other DNAs that scored positive
for episome persistence.
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To define the
cis-acting element upon which LANA1 acts to
mediate episome persistence, Z6-BE, Z6-3TRA, Z6-2TR, Z6-1TR, and
Z6-A
(Fig.
1) were each transfected into BJAB/F-LANA1 cells (
4)
or BJAB cells and selected for G418 resistance (conferred by the
plasmid vector). Z6-BE, Z6-3TRA, and Z6-2TR DNA efficiently persisted
in BJAB/F-LANA1 cells, and over 95% of microtiter wells had easily
detectable macroscopic cell clumps, each containing at least several
hundred cells, by ~10 days posttransfection. Z6-1TR also persisted
in
BJAB/F-LANA1 cells in over 95% of microtiter wells, although
the wells
had smaller macroscopic cell clumps at ~10 days posttransfection
and
hence the cells took longer to acidify the medium than after
transfection with Z6-BE, Z6-3TRA, or Z6-2TR. However, after several
weeks in culture there was no obvious difference between the
growth
of G418-resistant BJAB/F-LANA1 cells transfected with Z6-1TR and
the growth of those transfected with Z6-BE, Z6-3TRA, or Z6-2TR.
Efficient outgrowth was F-LANA1 dependent since only ~20% of
microtiter
wells were positive for outgrowth after transfection of
Z6-BE,
Z6-3TRA, Z6-2TR, or Z6-1TR into BJAB cells and G418 selection.
Although Z6-A contains truncated TR sequence, it lacks a
cis-acting
component necessary for efficient persistence. In
contrast to
the efficient G418-resistant outgrowth (in over 95%
of microtiter
wells) after transfection of DNA containing unit-length
TR sequence
into BJAB/F-LANA1 cells, only ~20% of microtiter
wells were positive
for outgrowth after Z6-A transfection into
BJAB/F-LANA1 cells
and G418 selection. A similar low level of
G418-resistant outgrowth
was observed after transfection of Z6-A into
BJAB cells. The Z6-A-transfected,
G418-resistant BJAB/F-LANA1 and BJAB
cells contain integrated
Z6-A DNA (see below). These results indicate
that unit-length
TR DNA, but not the truncated TR sequence in A,
efficiently persists
in F-LANA1-expressing cells. Of note, the
truncated TR sequence
in A lacks the 20-nt LANA1 binding sequence
defined
below.
LANA1 acts in trans on KSHV TR DNA to mediate
long-term episome persistence.
Since efficient outgrowth of
F-LANA1-expressing cells transfected with TR DNA is consistent with
episome persistence, Gardella gel analysis was performed on
G418-resistant cells to assay for episomes. In Gardella gels, live
cells are lysed in situ in the gel wells at the start of the gel run.
Episomal DNA (as large as 200 kb) migrates into the gel, whereas
chromosomal DNA is unable to migrate into the gel (17). As
expected, BC-1 (Fig. 2A, lane 1) and
BCBL-1 (Fig. 2A, lane 3; Fig. 2B, lane 1) KSHV-infected PEL cells had
episomal DNA whereas uninfected BJAB cells did not (Fig. 2, lanes 2).
After 2 weeks of G418 selection, BJAB/F-LANA1 cells that had been
transfected with Z6-3TRA (Fig. 2A, lanes 4 to 8), Z6-2TR (lanes 9 to
13), or Z6-BE (lanes 14 to 18) had episomal DNA. Because of their
slower initial outgrowth in microtiter plates, BJAB/F-LANA1 cells
transfected with Z6-1TR and Z6-A and BJAB cells transfected with
Z6-3TRA, Z6-2TR, Z6-1TR, Z6-BE, and Z6-A could not be assayed for
extrachromosomal DNA after 2 weeks of G418 selection.
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FIG. 2.
LANA1 acts on cis-acting unit-length KSHV TR
DNA to mediate episome persistence. (A) G418-resistant BJAB/F-LANA1
cells (2 × 106) transfected with Z6-BE, Z6-3TRA, or
Z6-2TR were lysed in situ in wells of Gardella gels, electrophoresis
was performed, DNA was transferred to a nylon membrane, and KSHV TR DNA
was detected. Lanes: 1, BC-1; 2, BJAB; 3, BCBL-1; 4 to 18, G418-resistant BJAB/F-LANA1 cells transfected with Z6-3TRA (lanes 4 to
8), Z6-2TR (lanes 9 to 13) or Z6-BE (lanes 14 to 18); 19, Z6-3TRA
plasmid; 20, Z6-2TR plasmid; 21, Z6-BE plasmid. The upper bands in
lanes 19 to 21 are from nicked plasmid DNA. The lower bands in lanes 1 and 3 are from linear and degraded virus DNA. The data shown are
representative of two experiments. (B) G418-resistant BJAB or
BJAB/F-LANA1 cells transfected with Z6-BE, Z6-3TRA, or Z6-A were
analyzed in Gardella gels. Lanes: 1 BCBL-1; 2, BJAB; 3 to 5, Z6-3TRA-transfected BJAB cells; 6 to 9, Z6-3TRA-transfected
BJAB/F-LANA1 cells; 10 to 12, Z6-A-transfected BJAB cells; 13 to 15, Z6-A-transfected BJAB/F-LANA1 cells; 16 to 18, Z6-BE-transfected BJAB
cells; 19 to 21, Z6-BE-transfected BJAB/F-LANA1 cells; 22, Z6-3TRA
plasmid; 23, Z6-A plasmid; 24, Z6-BE plasmid. The upper bands in lanes
22 to 24 are from nicked plasmid DNA. The lower band and smear in lane
1 is from linear and degraded DNA. The data shown are representative of
two experiments. O, well origins.
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Gardella gel assays for episomes were repeated after 1 month of G418
selection. Z6-3TRA (Fig.
2B, lanes 6 to 9) and Z6-BE
(lanes 19 to 21),
continued to persist as episomes in BJAB/F-LANA1
cells, and
BJAB/F-LANA1 cells transfected with Z6-2TR or Z6-1TR
also had episomes
(data not shown). Episomes persisted for as
long as 7 months in
BJAB/F-LANA1 cells (data not shown). In contrast,
BJAB/F-LANA1 cells
that had grown out as G418 resistant after
transfection with Z6-A (Fig.
2B, lanes 13 to 15) did not have
extrachromosomal DNA. After
transfection of LANA1-negative BJAB
cells and G418 selection, Z6-3TRA
(Fig.
2B, lanes 3 to 5), Z6-A
(lanes 10 to 12), Z6-BE (lanes 16 to 18),
Z6-2TR, and Z6-1TR (data
not shown) did not have episomal DNA. These
cells had transfected
DNA as demonstrated by PCR, and upon longer
exposures of Southern
blots of Gardella gels, DNA was sometimes
detected at the loading
wells, consistent with the presence of
integrated DNA in these
cells (data not shown). Since episomal DNA
persisted in BJAB/F-LANA1
cells only after transfection of DNA
containing one or more complete
TR elements, these data demonstrate
that F-LANA1 acts on unit-length
KSHV TR DNA to mediate episome
persistence. The truncated TR sequence
in Z6-A (which lacks the LANA1
binding sequence defined below)
is insufficient for F-LANA1-mediated
episome
maintenance.
A decrease in episome migration rate in Gardella gels, consistent with
an increase in episome size, was observed over time.
For instance,
after 2 weeks of G418 selection, most extrachromosomal
Z6-3TRA (Fig.
2A, lanes 4 to 8) and Z6-BE (lanes 14 to 18) DNA
comigrated with
covalently closed circular plasmid (lanes 19 and
21, respectively), but
after 1 month of selection, almost all
Z6-3TRA (Fig.
2B, lanes 6 to 9)
and much of Z6-BE (lanes 19 to
21) extrachromosomal DNA migrated at a
rate similar to that of
~170-kb (
42) viral BCBL-1
episomes (lane 1). Similar decreases
in migration rates were observed
with other artificial KSHV episomes.
Initial Southern blot
analyses of Hirt-extracted DNA (
20) from
BJAB/F-LANA1
cells containing large episomes and restriction enzyme
analyses of
plasmids transferred from BJAB/F-LANA1 cells to bacteria
indicate that
the slower migration is due to TR duplication and
arrangement of input
plasmids into multimers (data not shown).
These findings are
reminiscent of multimerization of input DNA
containing partial EBV oriP
sequences in EBNA1-expressing cells,
with a resultant increase in EBNA1
binding sites per episome (
11,
51).
Immunoprecipitated F-LANA1 binds KSHV TR restriction
fragments.
Since KSHV TR DNA is necessary and sufficient for
LANA1-mediated episome persistence, we investigated whether LANA1
associates with TR DNA. TR restriction fragments (Fig.
3A) were assayed for the ability to bind
anti-FLAG M2 or isotype-matched control antibody immunoprecipitates
from BJAB/F-LANA1 cells. F-LANA1 immunoprecipitate (Fig.
3B, lane 3) bound sixfold more NotI-AscI 535-nt
TR fragment than did control immunoprecipitate (lane 4, arrow) (input
NotI-AscI 535-nt TR probe [Fig. 3B, lane 6]).
In contrast, there was no significant difference between the low level
of binding of F-LANA1 (lane 1) and control (lane 2, arrowhead)
immunoprecipitates to the NotI-AscI 266-nt TR
fragment (input NotI-AscI 266-nt TR probe [Fig.
3B, lane 5]). Since F-LANA1 immunoprecipitate specifically bound the
NotI-AscI 535-nt fragment, binding to this
fragment was further investigated by assaying the
NotI-AvaII 297-nt and Sau3A-AscI 370-nt restriction fragments (Fig. 3A)
for F-LANA1 binding. F-LANA1 immunoprecipitate (Fig. 3C, lane 1) bound
12-fold more NotI-AvaII 297-nt TR fragment than
did control immunoprecipitate (lane 2, arrowhead) (input
NotI-AvaII 297-nt TR probe [Fig. 3C, lane 5]).
F-LANA1 immunoprecipitate (Fig. 3C, lane 3) bound 17-fold more
Sau3A-AscI 370-nt TR fragment than did control
immunoprecipitate (lane 4, arrow) (input
Sau3A-AscI 370-nt TR probe [Fig. 3C, lane 6]).
Since both the the NotI-AvaII 297-nt and
Sau3A-AscI 370-nt fragments specifically bound
F-LANA1 immunoprecipitates, these findings are consistent with the
possibility that F-LANA1 binds to a site(s) within the 132-bp
overlapping region between these fragments.
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FIG. 3.
KSHV TR DNA restriction fragments are bound by
immunoprecipitated F-LANA1. Radiolabeled KSHV TR restriction fragments
were incubated with F-LANA1 or control immunoprecipitates from
BJAB/F-LANA1 cells. Bound restriction fragments were eluted and
resolved on 5% nondenaturing polyacrylamide gels. (A) Restriction map
of the KSHV TR. Numbers indicate the the length of restriction
fragments in nucleotides. (The NotI restriction site is at
TR nt 383 [43].) Only the nonmethylated AvaII
site is shown. (B) F-LANA1 (lanes 1 and 3) or control (lane 2 and 4)
immunoprecipitates were incubated with the 266-bp
NotI-AscI probe (lanes 1 and 2) or the 535-bp
NotI-AscI probe (lanes 3 and 4); input 266-bp
NotI-AscI probe (lane 5) and input 535-bp
NotI-AscI probe (lane 6) are also shown. The
arrow indicates the 535-bp NotI-AscI probe, and
the arrowhead indicates the 266-bp NotI-AscI
probe. All lanes are from the same gel and have the same exposure time.
(C) F-LANA1 (lanes 1 and 3) or control (lane 2 and 4)
immunoprecipitates were incubated with the 297-bp
NotI-AvaII probe (lanes 1 and 2) or the 370-bp
Sau3A-AscI probe (lanes 3 and 4); the input
297-bp NotI-AvaII probe (lane 5) and the input
370-bp Sau3A-AscI probe (lane 6) are also shown.
All lanes are from the same gel and have the same exposure time. The
arrow indicates the 370-bp Sau3A-AscI probe, and
the arrowhead indicates the 297-bp NotI-AvaII
probe. The data shown are representative of three experiments.
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F-LANA1 binds specific TR sequence in EMSA analysis.
EMSA
experiments with oligonucleotides TR-8, TR-7, TR-2, and TR-3 (Fig.
4A) were performed to assay F-LANA1
binding within the 132-nt overlapping region between the
NotI-AvaII 297-nt and Sau3A-AscI 370-nt TR fragments. In vitro
translated F-LANA1 (Fig. 5, lanes 1, 2, 4, 5, 7, 8, 10 and 11) or RBP-J
(lanes 3, 6, 9, and 12) was
incubated with radiolabeled TR-8, TR-7, TR-2, or TR-3, and EMSA was
performed. RBP-J is a DNA binding protein that lacks a cognate
sequence in TR-8, TR-7, TR-3, and TR-2 (18, 19). F-LANA1
(Fig. 5, lanes 1, 4, and 10) and RBP-J (lanes 3, 6, and 12) gel
shifts were faint and similar for TR-8, TR-7, and TR-3 probes,
indicating only nonspecific gel shifts. However, F-LANA1 (lane 7, arrow) generated a specific TR-2 gel shift not observed with RBP-J
(lane 9). A 50-fold excess of nonradiolabeled oligonucleotide of the
same sequence as the radiolabeled probe competed the specific gel shift
(lane 8). These results indicate that F-LANA1 specifically gel shifts
TR-2 but not TR-3, TR-7, or TR-8.
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FIG. 4.
KSHV TR oligonucleotides. (A) The positions of TR-8,
TR-7, TR-2, and TR-3 within the 132-bp
Sau3A-AvaII fragment of the KSHV TR are shown
schematically, TR-8 extends 7 nt 5' to the Sau3A site. The
sequence between TR-7 and TR-8 and the sequence 3' to TR-3 was not
synthesized. The sequences of TR-8, TR-7, TR-2 and TR-3 are shown.
Sequences common to TR-7 and TR-2 are underlined, and the overlapping
sequence between TR-2 and TR-3 is shown in bold type. (B) The positions
of TR-11, TR-12, and TR-13 within TR-2 are shown schematically.
Identical sequence is aligned.
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FIG. 5.
In vitro-translated F-LANA1 gel shifts TR-2. TR-8 (lanes
1 to 3), TR-7 (lanes 4 to 6), TR-2 (lanes 7 to 9) and TR-3 (lanes 10 to
12) 32P-labeled oligonucleotides were each incubated with
in vitro-translated F-LANA1 (lanes 1, 2, 4, 5, 7, 8, 10, and 11) or
RBP-J (lanes 3, 6, 9, and 12), and EMSA was performed. A 50-fold
excess of unlabeled TR-8 (lane 2), TR-7 (lane 5), TR-2 (lane 8), or
TR-3 (lane 11) oligonucleotide was included in the incubation. The
arrow indicates the specific gel shift in lane 7, and the asterisk
indicates free probe. Data shown are representative of two
experiments.
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Localization of a 20-nt LANA1 binding sequence in TR-2.
To
further define the binding domain of F-LANA1 within TR-2, the
oligonucleotides which comprise TR-2 (TR-11, TR-12, and TR-13) (Fig.
4B) were each assayed for the ability to compete the F-LANA1 TR-2 gel
shift. F-LANA1 (Fig. 6A, lane 1, left
arrow) again specifically gel shifted TR-2 compared to RBP-J (lane
3), and the complex was competed with a 50-fold excess of unlabeled
TR-2 (lane 2). Both 50- and 100-fold excesses of unlabeled TR-13
competed the F-LANA1 TR-2 gel shift (lanes 8 and 9). TR-11 was
intermediate in its ability to compete the F-LANA1 TR-2 gel shift,
since a 100-fold excess (lane 5) but not a 50-fold excess (lane 4) of TR-11 competed the shift. TR-12 did not compete the F-LANA1 gel shift
at any concentration (lanes 6 and 7). Therefore, TR-13 competed the
TR-2 gel shift more efficiently than did TR-11, and TR-12 did not
compete the F-LANA1 shift at all. Since TR-11 and TR-13 overlap by 7 nt
(Fig 4B), this result indicates a role for these nucleotides in
competing with TR-2 for F-LANA1 binding.
View larger version (55K):
[in this window]
[in a new window]
|
FIG. 6.
Delineation of F-LANA1 binding within TR-2. (A)
Competition for TR-2 binding to F-LANA1 with oligonucleotides
comprising TR-2. In vitro-translated F-LANA1 was incubated with TR-2
prior to EMSA in all lanes except lane 3, where RBP-J was used. A
50-fold molar excess of unlabeled TR-2 was incubated with F-LANA1 for 5 min before addition of TR-2 probe (lane 2). A 50-fold (lanes 4, 6, and
8) or 100-fold (lanes 5, 7, and 9) molar excess of unlabeled TR-11,
TR-12, or TR-13 was incubated with F-LANA 1 before the addition of TR-2
probe. The arrow indicates specific gel shifts, and the asterisk
indicates free probe. (B) F-LANA1 specifically gel shifts TR-13. In
vitro-translated F-LANA1 (lanes 1, 2, 4, 5, 7, and 8) or RBP-J
(lanes 3, 6, and 9) was incubated with radiolabeled TR-11 (lanes 1 to
3), TR-12 (lanes 4 to 6), or TR-13 (lanes 7 to 9) (indicated at the
top). A 50-fold excess of unlabeled oligonucleotide was included in the
incubation (lanes 2, 5, and 8). Asterisk indicates unbound probe. NSB,
nonspecific band. (C) Excess nonradiolabeled TR-13 specifically
competes the TR-13 gel shift. In vitro-translated F-LANA1 was incubated
with radiolabeled TR-13. A 10-, 50-, or 100-fold excess of unlabeled
TR-13 was included in the incubation in lanes 2, 3, and 4 respectively.
A 50- or 100-fold excess of unlabeled TR-12 was included in the
incubations in lanes 5 and 6, respectively. Free probe was run off the
gel. U, upper F-LANA1 TR-13 gel-shifted complex; L, lower F-LANA1 TR-13
gel-shifted complex. Unlabeled competitor oligonucleotides are
indicated at the bottom. Data shown are representative of two
experiments.
|
|
The ability of F-LANA1 to gel shift TR-11, TR-12, and TR-13 was
assayed. Consistent with the inability of TR-12 to compete
the TR-2 gel
shift (Fig.
6A), F-LANA1 did not specifically gel
shift TR-12 (Fig.
6B,
lane 4 [compare to RBP-J
in Fig.
6B, lane
6]). Despite the finding
that a 100-fold excess of TR-11 competed
the TR-2 gel shift (Fig.
6A, lane 5), F-LANA1 did not specifically
shift TR-11 (Fig.
6B, lane 1 [compare to RBP-J
in Fig.
6B, lane
3]). Consistent with the
efficient competition by TR-13 of the
TR-2 gel shift (Fig.
6A), F-LANA1
specifically gel shifted TR-13
(Fig.
6B, lane 7, right arrows [compare
to RBP-J
in Fig.
6B,
lane 9]). Excess nonradiolabeled competitor
oligonucleotides competed
all gel shifts (Fig.
6B, lanes 2, 5, and 8).
The nonspecific band
in Fig.
6B (lanes 1, 3, 4, 6, 7 and 9) was greatly
diminished
when poly(dI-dc) at 20 µg/ml (Fig.
6C) rather than 1 µg/ml (Fig.
6B) was included in the EMSA binding buffer. Further,
anti-FLAG
antibody supershifted only the specific F-LANA1 gel shifts
(see
below) and not the nonspecific band (data not shown). Competition
of the F-LANA1 TR-13 gel shifts by excess, unlabeled TR-13 was
very
efficient. A 10-fold excess of unlabeled TR-13 competed most
of the
TR-13 gel shifts (Fig.
6C, lane 2) and 50- and 100-fold
excesses of
TR-13 (lanes 3 and 4, respectively) competed all the
TR-13 gel shifts.
In contrast, a 50- or 100-fold excess of unlabeled
TR-12 did not
compete the TR-13 gel shifts (lanes 5 and 6). The
upper TR-13 gel shift
(Fig
6B, lane 7; Fig.
6C) was routinely
resolved into two complexes on
longer gel runs (Fig.
7A, lanes
1 and 4).
View larger version (70K):
[in this window]
[in a new window]
|
FIG. 7.
Supershift analyses of F-LANA1 and PEL cell nuclear
extracts with TR-13. (A) Anti-FLAG antibody supershifts F-LANA1 TR-13
complexes. In vitro-translated F-LANA1 was incubated with TR-13 probe
for all lanes. A 50-fold excess of unlabeled TR-13 oligonucleotide
(lane 2), monoclonal anti-FLAG antibody (lane 3), or isotype-matched
control antibody (lane 4) was added 15 min prior to the addition of
50,000 cpm of TR-13. Arrows indicate specific gel shifts. U, upper
F-LANA1 shifted complex seen in Fig. 6B and C, which is resolved into
two complexes here after a longer gel run; L, lower F-LANA1 gel-shifted
complex. Data shown are representative of three experiments. Free probe
was run off the gel. (B) LANA1 from PEL cells gel shifts TR-13. EMSA
was performed using TR-13 probe and nuclear extracts from BCBL-1 (lanes
1 to 4), BC-1 (lanes 5 to 8) or (uninfected) BJAB cells (lanes 9 to
12). A 50-fold molar excess of unlabeled TR-13 (lanes 2, 6, and 10),
anti-LANA1 monoclonal antibody (lanes 3, 7, and 11), or control
antibody (lanes 4, 8, and 12) were included in incubations prior to the
addition of 50,000 cpm of TR-13 probe. The arrows indicate specific gel
shifts, and the arrowhead indicates supershifted probe near the gel
origin (lanes 3 and 7). NSB, nonspecific band. Free probe is indicated
by an asterisk. Data shown are representative of three experiments.
|
|
Supershift analyses with F-LANA1 and LANA1 from PEL cells.
To
confirm the presence of F-LANA1 in the TR-13 gel-shifted complexes,
supershift assays with anti-FLAG antibody were performed. Anti-FLAG
(Fig. 7A, lane 3), but not an isotype-matched control antibody
(lane 4), induced supershifts of both the upper and lower F-LANA1/TR-13
complexes (lane 1). Excess unlabeled TR-13 competed the gel shifts
(lane 2). These results demonstrate that these complexes contain
F-LANA1.
Since KSHV-infected PEL cells express LANA1, PEL cell nuclear extracts
were assayed for the ability to gel shift TR-13 probe
(Fig.
7B).
Specific LANA1 complexes were identified with anti-LANA1
monoclonal
antibody. EMSA with nuclear extract from BCBL-1 PEL
cells (Fig.
7B,
lane 1, arrows) gel shifted two complexes which
were supershifted with
LANA1-specific antibody (lane 3, arrowhead)
but not control antibody
(lane 4). BC-1 PEL cell nuclear extract
(lane 5) gel shifted a complex
which comigrated with the upper
BCBL-1 complex (lane 1, upper arrow)
and which also supershifted
with antibody to LANA1 (lane 7, arrowhead) but not control antibody
(lane 8). Excess
unlabeled TR-13 competed the LANA1 complexes
(lanes 2 and 6).
Incubation of TR-13 probe with BJAB (uninfected)
nuclear extract (lanes
9 to 12) did not result in specific gel
shifts. These results indicate
that BCBL-1 and BC-1 nuclear extracts
gel shift TR-13 in complexes that
contain
LANA1.
| |
DISCUSSION |
This work demonstrates that LANA1 acts in trans on
cis-acting KSHV TR DNA to mediate episome persistence and
that LANA1 specifically binds KSHV TR DNA. Plasmids containing
one or more TR units persisted as episomes in F-LANA1-expressing
cells but not in cells lacking F-LANA1. Immunoprecipitated F-LANA1 but
not control immune precipitates specifically bound certain TR
restriction fragments. Specific TR oligonucleotides were gel shifted by
in vitro-translated F-LANA1, and a 20-nt LANA1 binding site (TR-13) was
defined. Nuclear extracts from BCBL-1 and BC-1 PEL cells specifically
gel shifted TR-13, and the presence of LANA1 in these complexes was
confirmed by supershift analyses. Z6-A DNA contains truncated TR
sequence but lacks the LANA1 binding site defined here (TR-13) and did
not persist as an episome in F-LANA1-expressing cells. Medveczky and colleagues have also shown that LANA1 binds to KSHV TR sequence (Medveczky et al., Third International Workshop on KSHV and Related Agents, abstr. 21, 2000). These data support a model in which LANA1
directly binds KSHV episomes via TR DNA to efficiently mediate episome persistence.
The high TR copy number (~40 copies) (28, 43) in genomic
KSHV may enhance LANA1-mediated episome persistence. The EBV oriP
contains 24 EBNA1 binding sites distributed among 20 tandem repeats and
a dyad symmetry element (29, 37, 41, 50, 52). More than
one EBNA1 binding site is required for efficient EBNA1 mediated episome
retention (11, 34, 51). Plasmids lacking the full
complement of EBNA1 binding sites may dimerize or form tetramers in
EBNA1-expressing cells, increasing the number of EBNA1 binding sites
per episome (11, 47). Although LANA1 may bind to
additional sites in the TR unit, the tandemly repeated TR
elements in genomic KSHV provide a large number of LANA1 binding sites.
Multimerization of input plasmid DNA and TR duplication (Fig. 2 and
data not shown) in artificial KSHV episomes increases the number of
LANA1 binding sites and suggests that this increase improves the
efficiency of LANA1-mediated episome maintenance.
It is likely that tandemly repeated TR elements mediate the focal
concentration of LANA1 to dots seen by immunofluorescence microscopy in
KSHV-infected cells (23, 24, 48). LANA1 localizes to dots
in BJAB/F-LANA1 cells with artificial KSHV episomes containing tandemly
repeated TR elements but is diffusely distributed in the nucleus in the
absence of KSHV episomal DNA (4). Localization of LANA1 to
dots was also observed in cells with episomal Z6-1TR, Z6-2TR, Z6-3TRA,
or Z6-BE DNA (data not shown). LANA1 concentration to dots in cells
with these artificial episomes may be dependent on increased numbers of
LANA1 binding sites from TR duplication and multimerization of input
plasmids, as occurred when cells proliferated over time. Also
consistent with the idea that DNA mediates the focal LANA1
concentration, DNase but not RNase treatment of BCBL-1 nuclei
eliminated the punctate nuclear immunofluorescent staining pattern
characteristic of LANA1 in PEL cells (49). LANA1 forms
dimers in the absence of KSHV DNA (44) and may also dimerize and oligomerize at binding sites, as suggested by the presence of three different F-LANA1 gel-shifted TR-13 complexes in EMSA
experiments (Fig. 7A, lane 1). By analogy, EBNA1 binds to its
cognate DNA sequence as a dimer, and dimerization is required for
binding (6, 10).
In order to persist, episomes must replicate at least once per cell
cycle in addition to efficiently segregating to progeny cells. DNA
replication initiates at or near the EBNA1 binding region of dyad
symmetry in the EBV oriP and at other sites in the EBV genome
during latency (16, 31). The dyad symmetry element, which
contains four EBNA1 binding sites, is also a site of termination of DNA
replication (14, 16). Although EBNA1 is necessary for
long-term persistence of EBV oriP episomes, its role in EBV DNA
replication remains controversial (1, 7, 10, 29, 32, 45, 51,
52). Whether LANA1 plays a role in KSHV DNA replication and how
the TR functions as an origin of replication await further investigation.
Open reading frame 73 genes of other gamma-2 herpesviruses may also act
on cognate TR DNA to mediate episome persistence. A
cis-acting oriP sequence has been defined for herpesvirus
saimiri (HVS), although the trans-acting factor has not been
described (27). Despite the HVS oriP location within the
long unique region of the genome, it is likely that HVS has an
additional region(s) involved in episome maintenance, perhaps in
the TR elements, since a strain of HVS lacking the described oriP
sequence persists as an episome (27, 33). Similar to KSHV,
HVS and other gamma-2 herpesviruses also have high TR copy numbers,
which may reflect a TR role in episome persistence.
The model of LANA1 tethering TR DNA to chromosomes to mediate episome
persistence requires simultaneous association of LANA1 with episomes
and chromosomes, and this work demonstrates that LANA1 directly
binds KSHV TR DNA. With respect to the association of LANA1 with
chromosomes, LANA1 may bind chromosomal DNA or chromosome-associated proteins to mediate episome persistence. In this regard, LANA1 binds to
histone H1, RING3, p53, members of the mSin3 corepressor complex, and
retinoblastoma protein (12, 15, 26, 36, 39), and it is
possible that any of these proteins may mediate its attachment to
chromosomes. The DNA binding domain of the EBV EBNA1 protein is
different from the domain involved in chromosome association (2,
10, 25, 29, 32, 45). Further investigation should elucidate the
functional domains of LANA1 and how they coordinate to mediate episome maintenance.
| |
ACKNOWLEDGMENTS |
We thank Elliott Kieff, Siu Chun Hung, Eric
Johanssen, and Stephanie Shauer for helpful discussions.
This work was supported by grants 5T32CA09031 and CA85751 (to M.E.B.)
and CA67380 and CA82036 (to K.M.K.) from the National Cancer Institute.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Medicine, Channing Laboratory, Brigham and Women's Hospital, Harvard Medical School, 181 Longwood Ave., Boston, MA 02115. Phone: (617) 525-4256. Fax: (617) 525-4251. E-mail:
kkaye{at}rics.bwh.harvard.edu.
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Journal of Virology, April 2001, p. 3250-3258, Vol. 75, No. 7
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.7.3250-3258.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
