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Journal of Virology, December 2000, p. 11479-11489, Vol. 74, No. 24
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Interaction between Hepatitis B Virus Core Protein
and Reverse Transcriptase
Lisa
Lott,1,2
Burton
Beames,1
Lena
Notvall,1 and
Robert E.
Lanford1,2,*
Department of Virology and Immunology,
Southwest Regional Primate Research Center, Southwest Foundation for
Biomedical Research, San Antonio, Texas 78227,1
and Department of Microbiology, University of Texas
Health Science Center at San Antonio, San Antonio, Texas
782292
Received 27 April 2000/Accepted 18 September 2000
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ABSTRACT |
Previous mutagenesis studies with hepatitis B virus (HBV) suggest
that continued interactions with core are required for several steps in
genomic replication. To examine core-polymerase (Pol) interactions,
insect cells were coinfected with baculovirus constructs that
independently expressed core and Pol. The results demonstrated several
features with implications that core plays an interactive role with HBV
Pol: (i) core coprecipitated with constructs expressing full-length Pol
as well as the terminal protein (TP), reverse transcriptase (RT) and
RNase H domains of Pol, independently; (ii) coprecipitation of core was
not dependent on the presence of an epsilon stem-loop sequence; and
(iii) core-Pol complexes migrated as intact capsid particles, as
detected by sucrose gradient analysis. To analyze the structural and
sequence requirements of core in recognition of Pol, a series of core
mutants with two- to four-amino-acid insertions or carboxy-terminal
deletions were assessed for Pol interaction. The results indicated that
capsid formation is required but not sufficient for interaction with Pol and that the TP and RT domains of Pol have different requirements for interaction with core. To map the core binding sites on Pol, a
panel of amino- and carboxy-terminal deletion mutants of the TP and RT
domains of Pol were analyzed for interaction with core. At least three
separate core binding sites on Pol were detected. This analysis begins
to define basic requirements for core-Pol interactions, but further
study is necessary to delineate the effects of these interactions on
encapsidation and genome replication.
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INTRODUCTION |
Hepatitis B virus (HBV) is a member
of the Hepadnaviridae family. Mature HBV virions are
enveloped and contain partially double stranded, non-covalently closed,
circular DNA with the viral polymerase (Pol) covalently bound to the
first deoxyribonucleotide of the 5' end of the minus-strand DNA. HBV
replicates by reverse transcription of a pregenomic RNA molecule which
occurs inside of a capsid particle (for reviews see references 11, 32,
and 39). For encapsidation and subsequent genomic replication to occur,
a ribonucleoprotein (RNP) complex forms between Pol and the epsilon
stem-loop structure on a pregenomic RNA molecule (2). The
epsilon stem-loop is present on both the 5' and 3' ends of pregenomic
RNA, but only the 5' copy of epsilon functions in vivo as a packaging
signal (14, 16, 18, 34). A sequence in a bulge in the 5'
copy of epsilon functions as a template for the first four nucleotides in DNA synthesis by a protein-primed reverse transcription reaction catalyzed by Pol (41, 42). Minus-strand DNA synthesis
continues after a translocation step in which the primed-Pol complex
translocates to a complementary sequence in the 3' copy of DR1 (8,
26, 29, 36-38, 44). Whether the priming reaction occurs after
packaging or prior to capsid assembly is not known, nor is the
mechanism by which the RNA-Pol RNP complex interacts with the capsid
protein to produce replication-competent HBV particles.
The HBV capsid is composed of a single type of protein that is referred
to as the core protein and consists of 183 amino acids. The core
protein spontaneously forms capsids in the absence of the pregenomic
RNA or Pol when expressed in insect cells (23), bacteria
(7), yeast (28), or Xenopus oocytes
(47). The core protein contains numerous phosphorylation
sites, with a cluster of sites located at the carboxy terminus. The
phosphorylation state of core is associated with conformational changes
in the capsid particle (46) which may have significant
function after the assembly of core particles and the encapsidation of
viral RNA (17, 35). The carboxy terminus of the HBV core
protein is very basic and contains four arginine-rich domains. Although this region is not necessary for particle formation, the carboxy terminus binds nucleic acids, which could facilitate encapsidation. Core exhibits DNA and RNA binding abilities in vitro, but no
specificity between core and HBV RNA has been demonstrated (10,
12, 27, 33) in the absence of Pol. Both the Pol molecule and an
epsilon stem-loop structure are essential for packaging, although
neither is required to be replication competent for encapsidation to
occur (1, 13).
Previous mutagenesis studies with HBV and duck hepatitis B virus (DHBV)
core examined the requirements of the capsid protein during
encapsidation and viral DNA synthesis (3, 4, 31, 35, 45).
Capsid formation and RNA encapsidation are not sufficient to ensure
efficient viral DNA synthesis. Schlicht and coworkers reported that the
deletion of 36 amino acids from the carboxy terminus of the DHBV core
protein abolished genome replication, although mutant cores formed
capsid particles competent for genome packaging (35). Yu and
Summers examined a series of deletions covering the 3' end of the DHBV
capsid open reading frame (ORF) and detected mutant phenotypes
supporting various levels of DNA synthesis, ranging from wild-type (WT)
DNA replication, to single-stranded DNA in the absence of relaxed
circular DNA, to mutants in which replication was severely reduced
(45). Studies with HBV core particles from transfected Huh7
cells revealed that when 12 amino acids were deleted from the carboxy
terminus, core particles supported WT levels of RNA packaging but were
defective in minus-strand DNA synthesis (3). Mutant proteins
truncated to amino acid 163 or 164 package RNA but are drastically
reduced in DNA synthesis (3, 31). Core proteins with further
deletion to amino acid 144 were assembly competent but did not package
RNA (3, 31). The observation that deletions in the carboxy
terminus of core cause a progressive loss of genome replication and
ultimately loss of RNA packaging suggests that continued and specific
interactions with core are required for several steps in genome replication.
In this study, we used a series of core insertion and carboxy-terminal
deletion mutants to examine the structural and sequence requirements of
core for interacting with HBV Pol. Previous studies using this system
have demonstrated that purified human HBV Pol expressed in insect cells
is active in protein-primed reverse transcription (24).
Furthermore, independent expression of the TP and RT domains of Pol
within the same cells results in the formation of a stable RNP complex
with epsilon that is active in nucleotide priming and reverse
transcription (25). In this study, insect cells were
coinfected with baculovirus constructs independently expressing core
and Pol. Immunoprecipitation reactions and treatment with RNase A
confirmed that an interaction exists between HBV core and Pol that is
not dependent on an epsilon stem-loop structure. In addition, core
coprecipitated with both the TP, RT, and RNase H domains, suggesting
that core interacts with at least three sites on Pol. Analysis of Huh7
cells coinfected with vaccinia virus constructs expressing core and Pol
revealed that core-Pol interaction extends to mammalian cells. Sucrose
gradient analysis demonstrated that Pol interacts with cores from
capsid fractions; however, coprecipitation assays between mutant cores and the TP or RT domain revealed that capsid formation is required but
not sufficient for these core-Pol interactions.
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MATERIALS AND METHODS |
Cells.
The Sf9 cell line derived from Spodoptera
frugiperda was maintained in spinner culture as described
previously (23). Sf9 cells were cultivated in TNMFH
supplemented with 5% fetal bovine serum and 0.1% pluronic F68. After
infections, the medium was changed to Grace's medium supplemented with
2% fetal bovine serum. The human hepatoma cell line Huh7
(30) was maintained in Dulbecco modified Eagle medium-F-12
medium (1:1) plus 10% fetal bovine serum, 2 mM glutamine,
and 50 µg of gentamicin per ml.
Plasmid constructs.
HBV sequences of the ayw
subtype are numbered as specified by Galibert and coworkers
(9). The core deletion and insertion mutants (Fig.
1A) were generated as described
previously (3, 4). Core proteins with carboxy-terminal
deletions are designated Cd followed by a number representing the last
carboxy-terminal amino acid. Insertions of two to four amino acids in
core are designated Ci followed by a number representing the location
of the insertion. The point mutation used for this study is designated Cp96 to denote a Lys-to-Arg mutation at amino acid 96.
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FIG. 1.
(A) Amino acid sequence of the core gene. Insertions
within the core gene are illustrated with the inserted amino acid
sequence in single-letter code. A single point mutation of Lys to Arg
is represented by a line at residue 96. Core deletions are illustrated
below the amino acid sequence and designated by arrows. (B) Structures
of FLAG-Pol constructs. FPL-pol depicts the structure of the WT Pol
construct. The pol ORF is designated by open rectangles. The
TP, spacer, RT, and RNase H domains are indicated below, and the GLY
and YMDD motifs are labeled above, the pol ORF. The F
indicates the presence of a 10-amino-acid FLAG sequence at the amino
terminus of Pol, which is illustrated by a solid bar; the L denotes an
epsilon stem-loop structure, which is present at the 3' end of the Pol
contructs. FTP225 denotes the amino-terminal 225 amino acids of Pol
with a FLAG epitope; F TPL denotes a deletion in the TP domain, but
the presence of a FLAG epitope and an epsilon stem-loop structure.
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The construct expressing full-length Pol, designated FPL-pol (Fig.
1B),
has the 10-amino-acid FLAG epitope (International
Biotechnologies Inc.,
New Haven, Conn.) fused to the amino terminus
as specified previously
(
24). The 3' terminus was extended beyond
the
pol
ORF to include DR1 and epsilon stem-loop sequences. All
Pol mutants
were generated as previously described (
22,
25).
FTP225
(Fig.
1B) contains the amino-terminal 225 amino acids of
Pol with a
FLAG epitope. F
TPL (Fig.
1B) denotes a deletion in
the TP domain of
Pol, but the presence of a FLAG epitope and an
epsilon stem-loop.
F
TP
3' denotes a deletion in the TP domain
and deletion of the 3'
extension containing DR1 and epsilon. FTP199
expresses the
amino-terminal 199 amino acids of Pol with a FLAG
epitope. The HCV
protein NS5B contains a FLAG epitope and was
provided as a control (C. Bigger, unpublished
data).
The vaccinia virus constructs FPL-pol and core contain an insert
identical to the FPL-pol in baculovirus. FPL-pol and core
were cloned
into the pVOTE2 vaccinia virus vector (
43), in which
expression is regulated by T7 RNA polymerase and is under
lac repression.
The deletion mutants of the TP and RT domains were created by PCR
mutagenesis as described previously (
22). The amino-terminal
deletions of TP and RT are named by the first amino acid at the
amino
terminus (e.g., FRTn300 for FLAG-RT from N-terminal amino
acid 300 through C-terminal amino acid 832 with an epsilon stem-loop,
and
FTPn20/c300 for FLAG-TP from N-terminal amino acid 20 through
C-terminal amino acid 300.) The carboxy-terminal deletions of
TP and RT
are named for the carboxy-terminal amino acid (e.g.,
FTPc300 spans
amino acids 1 to 300, and FRTc800 spans amino acids
176 to 800). A
minimal RNase H construct (FRNH) spans amino acids
680 to 780 and
contains a FLAG
epitope.
Immunoprecipitation.
Pol proteins were immunoprecipitated
with anti-FLAG affinity beads (M2 monoclonal antibody beads; Sigma).
Insect cells were infected or coinfected with baculovirus constructs,
harvested at 48 h postinfection by washing two times in
phosphate-buffered saline (PBS), and extracted with PEB (PBS containing
10% glycerol, 0.5% Nonidet P-40, and protease inhibitors [100 µM
leupeptin, 1 mM Pefabloc, 10 µM aprotinin, 10 µg of pepstatin per
ml, and 1 mM EDTA]). Clarified cell lysates were immunoprecipitated
with anti-FLAG affinity beads for 2 h at 4°C. The beads were
washed with PEB, one time with PEB-1 M NaCl, and a final time with
PEB. Huh7 cells were coinfected with vaccinia virus constructs,
harvested at 24 h postinfection and immunoprecipitated as
described above.
SDS-PAGE and immunoblot analysis.
Immunoprecipitated
complexes were disrupted in electrophoresis sample buffer containing
2% sodium dodecyl sulfate (SDS) and 2% 2-mercaptoethanol and were
heated to 100°C for 10 min. Proteins were separated by
SDS-polyacrylamide gel electrophoresis (PAGE) as previously described
(19, 20), and immunoblot analysis was performed by
electrophoretically transferring proteins to a Flurotrans
polyvinylidene difluoride blotting membrane (Pall Biosupport, Glen
Cove, N.Y.). Membranes were processed as previously described
(21), using iodinated M2 monoclonal antibody to detect the
FLAG epitope on Pol or with a rabbit anticore polyclonal antibody followed by 125I-protein A (NEN, Boston, Mass.).
Sucrose gradient analysis.
Core and Pol proteins expressed
in insect cells were analyzed by sucrose gradient centrifugation
followed by immunoblotting. Clarified cell lysates from infected Sf9
cells were applied to 5-ml gradients of 10 to 50% sucrose in PBS, and
sedimentation was performed in a Beckman SW55 rotor at 40,000 rPM
(approximately 200,000 × g) for 2 h. Ten 0.5-ml
fractions were collected, and a portion of each fraction was analyzed
by SDS-PAGE and immunoblotting as described above.
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RESULTS |
Core coprecipitates with the TP and RT domains of Pol in the
absence of epsilon.
To examine potential interactions between core
and Pol, insect cells were coinfected with baculoviruses independently
expressing core and Pol proteins, and core-Pol complex formation was
evaluated by coprecipitation studies. All Pol constructs contained a
FLAG epitope fused to the amino terminus of Pol; thus, Pol was
immunoprecipitated with anti-FLAG antibodies, and coprecipitation of
core was detected by Western blotting with anticore antibodies.
Immunoprecipitates were immunoblotted with anti-FLAG antibodies to
demonstrate the level of immunoprecipitated Pol (Fig.
2B). A fraction of the cell lysates were
immunoblotted with anticore antibodies to detect core protein
expression (Fig. 2A). Coinfection of insect cells with core and FPL-pol
indicated that core is able to coprecipitate with full-length Pol (Fig.
2C). No core was immunoprecipitated in the absence of Pol. Coinfection
of insect cells with baculoviruses expressing WT core and the TP
(FTP225) or RT (FTP3') domain of Pol revealed that core
coprecipitates with at least two sites on Pol (Fig. 2C). The fact that
core was able to coprecipitate with TP (FTP225) and RT (FTP3')
lacking epsilon stem-loop structures revealed that epsilon is not
required for these core-Pol interactions.
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FIG. 2.
Interaction of core with the TP and RT domains of Pol.
Insect cells were coinfected with baculoviruses expressing core and a
Pol construct. (A) A fraction (1/20) of the cell lysate was
immunoblotted with anticore antibodies to confirm that the core protein
was expressed. (B) Pol proteins were immunoprecipitated (IP) and
immunoblotted with anti-FLAG antibodies. (C) Coprecipitation of core
was detected by Western blot analysis with anticore antibodies. The
negative control (No pol) is a single infection with WT core,
illustrating that core does not immunoprecipitate with M2 affinity
beads. Core coprecipitates with full-length Pol (FPL-pol) and with
FTP225 and FTP3', TP and RT constructs that lack epsilon
stem-loop structures.
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To determine whether core was interacting with the FLAG epitope rather
than Pol itself, we coinfected insect cells with baculoviruses
expressing WT core and the HCV protein NS5B that contains a FLAG
epitope. NS5B was immunoprecipitated with anti-FLAG antibodies,
and
Western blot analysis was performed with a mixture of anti-FLAG
and
anticore antibodies to detect precipitation of NS5B and coprecipitation
of core. A fraction of the cell lysate was immunoblotted with
anti-FLAG
antibodies and anticore antibodies to confirm protein
expression (Fig.
3A). The results revealed that NS5B but
not core
immunoprecipitated with anti-FLAG antibodies, indicating
that
core does not interact with the FLAG epitope (Fig.
3B).
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FIG. 3.
Core does not interact with the FLAG epitope on Pol. (A)
Insect cells were coinfected with baculoviruses expressing WT core and
the HCV protein NS5B that contains a FLAG epitope. A fraction (1/20) of
the cell lysate was immunoblotted with anticore antibodies to confirm
that the core protein was expressed. (B) Immunoprecipitation (IP) was
performed with anti-FLAG antibodies, and Western blot analysis was
performed with a mixture of anticore and anti-FLAG antibodies. NS5B
immunoprecipitates with anti-FLAG antibodies. Core does not
coprecipitate with anti-FLAG antibodies or with NS5B.
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Detection of core-Pol complex formation in Huh7 cells.
To
determine if a core-Pol complex forms when the proteins are expressed
in mammalian cells, Huh7 cells were coinfected with vaccinia virus
constructs expressing WT core and full-length Pol. The Pol proteins
were immunoprecipitated with anti-FLAG antibodies, and Western blot
analysis was performed with anticore and anti-FLAG antibodies. A
fraction of the cell lysate was immunoblotted to confirm core protein
expression (Fig. 4A). Pol protein
expression is lower than core expression and was detected only after
immunoprecipitation with anti-FLAG antibodies (Fig. 4B).
Coprecipitation of core confirmed that core-Pol interaction extends to
mammalian cells.
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FIG. 4.
Core-Pol interaction in mammalian cells. Huh7 cells were
coinfected with vaccinia virus constructs expressing core and Pol. The
negative control (No pol) is a single infection with WT core. (A) A
fraction (1/20) of the cell lysate was immunoblotted with anti-FLAG and
anticore antibodies. (B) Lysates were immunoprecipitated (IP) with
anti-FLAG antibodies to Pol and immunoblotted with anti-FLAG and
anticore antibodies. WT core coprecipitates with HBV Pol expressed in
liver cells.
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Treatment with RNase A does not disrupt core-Pol interactions.
Although epsilon was not required for core-Pol complex formation, this
did not rule out the possibility that the interaction was dependent on
an RNA intermediate. To test this possibility, we coinfected insect
cells with baculoviruses expressing core and TP, RT, or full-length Pol
and then immunoprecipitated the Pol proteins with anti-FLAG antibodies.
Identical sets of immunoprecipitates were incubated for 30 min at
37°C in the presence or absence of RNase A (50 µg/ml), while the
proteins were still bound to the affinity beads. The beads were washed
to remove any core released during the RNase treatment, and the
resulting immunoprecipitates were examined by Western blotting with
anticore antibodies (Fig. 5). No
difference in the level of coprecipitated core was observed in the
treated and untreated immunoprecipitates. Although the presence of a
small, protected RNA fragment cannot be excluded, the results suggest
that RNA is not required to maintain the interaction between core and
Pol.
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FIG. 5.
Treatment with RNase A does not disrupt core-Pol
interactions. Insect cells were coinfected with baculoviruses
expressing core and TP, RT, or full-length Pol, and the Pol proteins
were immunoprecipitated with anti-FLAG antibodies. The control (No pol)
is a single infection with WT core followed by immunoprecipitation with
anti-FLAG antibodies. Core-Pol complexes were incubated for 30 min at
37°C in the presence or absence of RNase A (50 µg/ml), while the
proteins were still bound to the affinity beads. The affinity beads
were washed to remove any core released by RNase treatment, and
coimmunoprecipitated core was analyzed by SDS-PAGE and Western blot
analysis with anticore antibodies.
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Interaction of TP and RT with carboxy-terminal deletion mutants of
core.
To analyze the structural and sequence requirements of core
for recognition of Pol, we used a series of carboxy-terminal
truncations of the 183-amino-acid core protein. Insect cells were
coinfected with baculoviruses expressing a core deletion mutant and TP
or RT. Core mutant proteins are designated Cd followed by the
carboxy-terminal amino acid number. A fraction of the cell lysate was
immunoblotted with anticore antibodies to detect core protein
expression (Fig. 6A). lmmunoprecipitation
and Western blot analysis was performed with anti-FLAG antibodies to
detect the Pol polypeptide (Fig. 6B), and immunoblotting with anticore
antibodies was used to detect coprecipitation of core (Fig. 6C). The
patterns of RT binding to the core deletion proteins were identical to
that of TP. The core deletion proteins Cd163, Cdl71, and Cd176
coprecipitated with TP and RT (Fig. 6C). Deletion to amino acid 148 abolished coprecipitation of core, although further deletion to amino
acid 144 restored core-Pol interaction. No binding to core deletions beyond amino acid 144 was detected. These results suggest that progressive deletion of amino acids from core may induce a change in
conformation, consequently preventing interaction between the core
deletion mutant Cd148 and the TP and RT domains of Pol. Further deletion to amino acid 144 may restore a conformation that permits a
binding interaction to occur. In addition, these results revealed that
at least one TP and RT binding site resides within the first 144 amino
acids of core. The data do not exclude the existence of additional
binding sites from amino acids 163 to 183.
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FIG. 6.
Interactions of TP and RT with carboxy-terminal deletion
mutants of core. Insect cells were coinfected with baculoviruses
expressing a core deletion mutant and TP or RT (FTPL). The control
(No TP or No RT) is a single infection with WT core. (A) A fraction
(1/20) of the cell lysate was immunoblotted with anticore antibodies to
confirm that the core protein was expressed. Immunoprecipitation (IP)
was performed with anti-FLAG antibodies followed by SDS-PAGE and
Western blot analysis with anti-FLAG antibodies (B) to show the
presence of TP and RT or with anticore antibodies (C) to detect
coprecipitation of core. Core mutants Cd144, Cd163, Cd171, and Cd176
coprecipitated with TP and RT, while core mutants Cd112, Cd135, and
Cd148 failed to coprecipitate with TP or RT.
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Interaction of core insertion mutants with TP and RT.
To
investigate the influence of two- to four-amino-acid insertions within
the core protein on core-Pol interactions, insect cells were coinfected
with baculoviruses expressing core insertion proteins and TP or RT.
Immunoprecipitation was performed with anti-FLAG antibodies for Pol,
followed by Western blot analysis with anticore antibodies. Core
insertion mutants are designated Ci to denote a two- to
four-amino-acid, in-frame insertion followed by the amino acid number
that corresponds to the site of insertion. Cp96, a point mutation at
amino acid 96, was used in this study. Core mutants with insertions at
the amino terminus, Ci11 and Ci36, and carboxy terminus, Ci126 and
Ci131, were unable to coprecipitate with TP or RT (Table
1). Mutants with insertions in the
central domain of core (Ci46, Ci67, Ci69, Ci89, and Cp96)
coprecipitated with both TP and RT. The core insertion mutant Ci44
coprecipitated with TP but not RT (Fig.
7C), revealing that in this instance, TP
and RT have different requirements for interacting with core.
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FIG. 7.
TP and RT differ in requirements for interacting with
core. Insect cells were coinfected with baculoviruses expressing a core
insertion mutant (Ci44, Ci46, or Ci89) and TP or RT (FTPL). (A) A
fraction (1/20) of the cell lysates were immunoblotted with anticore
antibodies to confirm that the core insertion mutants were expressed.
(B) Immunoprecipitation (IP) was performed with anti-FLAG antibodies,
followed by immunoblotting with anti-FLAG antibodies to confirm that
the TP and RT polypeptides were expressed and immunoprecipitated. (C)
Immunoprecipitation was performed with anti-FLAG antibodies, followed
by immunoblotting with anticore antibodies. Ci46 and Ci89
coprecipitated with both TP and RT, while Ci44 failed to coprecipitate
with RT.
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Pol interacts with HBV capsid particles.
Sucrose gradient
analysis was performed to determine the molecular form of core that
coprecipitated with Pol. Insect cells were coinfected with
baculoviruses expressing WT core and full-length Pol. The clarified
lysates were separated by velocity sedimentation on 10 to 50% sucrose
gradients and immunoblotted with anticore antibodies. The WT core
protein formed capsid particles which sedimented near the middle of the
gradient, and a small amount of dimeric core sedimented at the top of
the gradient (Fig. 8A). Immunoblot
analysis of gradient fractions of FPL-pol expressed from a single
infection (Fig. 8B), or from a coinfection with baculoviruses
expressing core (Fig. 8C), revealed similar distribution patterns in
which Pol proteins were distributed throughout the top and middle of
the gradients (fractions 2 to 5). Immunoblot analysis of the core
protein coprecipitating with Pol revealed that Pol interacts with cores
from capsid fractions (Fig. 8D). Pol was detected primarily in
noncapsid fractions; however, the amount Pol in association with core
is below our level of detection. The failure to detect Pol in the
fractions in which core coprecipitated suggests that a small percentage
of the Pol enters into the core-Pol interaction, indicative of a high
core-to-Pol ratio, perhaps approaching the stoichiometry observed in
virions.
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FIG. 8.
Pol interacts with capsid particles. Insect cells were
infected with baculoviruses expressing FPL-pol or coinfected with WT
core and FPL-pol. The clarified lysates were sedimented in 5-ml 10 to
50% sucrose gradients at 200,000 × g for 2 h.
Ten 0.5-ml fractions were collected, and a portion was analyzed by
SDS-PAGE and Western blot analysis. (A) The WT core protein from a
coinfection with FPL-pol formed capsid particles that sedimented
primarily in fractions 5 to 7. Immunoblot analysis was performed with
anticore antibodies. Immunoprecipitation and immunoblot analysis were
performed with anti-FLAG antibodies to FPL-pol expressed from a single
infection (B) or from a coinfection with WT core (C). (D) Gradient
fractions from a coinfection with FPL-pol and WT core were
immunoprecipitated (IP) with anti-FLAG antibodies and immunoblotted
with anticore antibodies to determine the molecular form of core that
interacts with Pol.
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Analysis of amino- and carboxy-terminal deletion mutants of TP for
interaction with core.
To map core binding sites on the TP
polypeptide, we analyzed several amino- and carboxy-terminal deletion
mutants of TP for the ability to coprecipitate core. Within the
carboxy-terminal deletion panel, the largest and smallest constructs
spanned amino acids 1 to 334 and 1 to 100, respectively, and contained
an amino-terminal FLAG epitope. The amino-terminal deletion panel
contained deletions of 20, 30, 50, and 60 amino acids from the 1-300 TP
construct. Insect cells were coinfected with baculovirus constructs
expressing core and a deletion mutant of the TP domain.
Immunoprecipitation and Western blot analysis was performed with
anti-FLAG antibodies to detect the TP deletion mutants (Fig. 9B and
10B),
followed by immunoblotting with anticore antibodies to detect
coprecipitation of core (Fig. 9C and 10C). Carboxy-terminal deletions
spanning to amino acid 175 were positive for coprecipitation of core,
indicating a core binding site on TP within the first 175 amino acids
(Fig. 9C). Constructs spanning from amino acids 1 to 150 and smaller were not well expressed, and coprecipitation of core could not easily
be interpreted; however, the level of core that coprecipitated with the
150- and 100-amino-acid TP polypeptides was greater than the negative
control. The amino-terminal deletion mutants of TP coprecipitated core,
with the largest deletion extending to amino acid 60 (Fig. 10C). This
indicates that a core binding site exists on TP between amino acids 60 and 300. Taken together, these data suggest a common binding site for
core on TP within amino acids 60 to 100. Alternatively, the data are
also consistent with the presence of at least two separate binding
sites, one in the amino terminus and one in the carboxy terminus of the
TP domain.
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FIG. 9.
Coprecipitation of core with carboxy-terminal deletion
mutants of the TP domain. Insect cells were coinfected with
baculoviruses expressing carboxy-terminal deletion mutants of the TP
domain and WT core. The control (No TP) is a single infection with WT
core. (A) A fraction (1/20) of the cell lysate was immunoblotted with
anticore antibodies to confirm that the core protein was expressed.
Immunoprecipitation (IP) was performed with anti-FLAG antibodies
followed by SDS-PAGE and Western blot analysis with anti-FLAG
antibodies (B) to show the presence of the TP polypeptides. A longer
exposure demonstrating polypeptides FTPc150 and FTPc100 is shown to the
right. (C) Western blot analysis with anticore antibodies demonstrates
that a definitive core binding site exists on TP between amino acids 1 and 175 and may exist in the polypeptide between amino acids 1 and
100.
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FIG. 10.
Coprecipitation of core with amino-terminal deletion
mutants of the TP domain. Insect cells were coinfected with
baculoviruses expressing amino-terminal deletion mutants of the TP
domain and WT core. The control (No TP) is a single infection with WT
core. (A) A fraction (1/20) of the cell lysate was immunoblotted with
anticore antibodies to confirm that the core protein was expressed.
Immunoprecipitation (IP) was performed with anti-FLAG antibodies
followed by SDS-PAGE and Western blot analysis with anti-FLAG
antibodies (B) to show the presence of the TP polypeptides or with
anticore antibodies (C) to detect coprecipitation of core. A core
binding site was detected on TP between amino acids 60 and 300.
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Analysis of amino- and carboxy-terminal deletion mutants of RT for
interaction with core.
To determine the core binding pattern on
the RT polypeptide, several amino- and carboxy-terminal deletion
mutants of the RT domain were analyzed for interaction with core. The
largest RT construct with a carboxy-terminal deletion spanned amino
acids 176 to 800 (FRTc800), and deletions extended to amino acid 550 (FRTc550). Within the amino-terminal deletion panel, the largest construct spanned amino acids 300 to 832 (FRTn300), and the smallest construct spanned amino acids 400 to 832 (FRTn400). Insect cells were
coinfected with baculovirus constructs expressing core and a deletion
mutant of the RT domain. Immunoprecipitation and Western blot analysis
were performed with anti-FLAG antibodies to detect the RT deletion
mutants (Fig. 11B and
12B)
followed by immunoblotting with anticore antibodies to detect
coprecipitation of core (Fig. 11C and 12C). All carboxy-terminal
deletion mutants were positive for coprecipitation of core, indicating
a core binding site on RT between amino acids 176 and 550 (Fig. 11C).
Core also coprecipitated with each of the amino-terminal deletion
mutants of the RT domain, identifying a core binding site on Pol
between amino acids 400 and 832 (Fig. 12C). One possibility to explain
the nature of these interactions is the presence of a common core
binding site on Pol between amino acids 400 and 550. However, the data
are also consistent with the presence of two or more core binding
sites, one in the amino terminus and one in the carboxy terminus of the RT polypeptides.
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|
FIG. 11.
Coprecipitation of core with carboxy-terminal deletion
mutants of the RT domain. Insect cells were coinfected with
baculoviruses expressing amino-terminal RT deletion mutants and WT
core. The control (No RT) is a single infection with WT core. (A) A
fraction (1/20) of the cell lysate was immunoblotted with anticore
antibodies to detect core protein expression. Immunoprecipitation (IP)
was performed with anti-FLAG antibodies followed by SDS-PAGE and
Western blot analysis with anti-FLAG antibodies (B) to show the
presence of the RT polypeptides or with anticore antibodies (C) to
detect coprecipitation of core. A core binding site extending from
amino acids 176 to 550 was detected on the RT polypeptide.
|
|
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|
FIG. 12.
Coprecipitation of core with amino-terminal deletion
mutants of the RT domain. Insect cells were coinfected with
baculoviruses expressing carboxy-terminal RT deletion mutants and WT
core. The control (No RT) is a single infection with WT core. (A) A
fraction (1/20) of the cell lysate was immunoblotted with anticore
antibodies to detect core protein expression. Immunoprecipitation (IP)
was performed with anti-FLAG antibodies followed by SDS-PAGE and
Western blot analysis with anti-FLAG antibodies (B) to show the
presence of the RT polypeptides or with anticore antibodies (C) to
detect coprecipitation of core. A core binding site was detected on Pol
between amino acids 400 and 832.
|
|
To test whether a core binding site was present in the carboxy terminus
of the RT constructs, we examined FRNH, a minimal
RNase H construct
which spanned amino acids 680 to 780. Insect
cells were coinfected with
baculovirus constructs expressing FRNH
and WT core. Immunoprecipitation
was performed with anti-FLAG
antibodies to FRNH, followed by Western
blot analysis with anti-FLAG
and anticore antibodies. The results
demonstrate that core coprecipitates
with a minimal RNase H polypeptide
(Fig.
13C).
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FIG. 13.
Core interacts with the RNase H domain. Insect cells
were coinfected with baculovirus constructs expressing FRNH and WT
core. The negative controls are a single infection with baculoviruses
expressing FRNH (FRNH Control) and a single infection with
baculoviruses expressing WT core (Core Control). (A) A fraction (1/20)
of the cell lysate was immunoblotted with anticore antibodies to detect
core protein expression. Immunoprecipitation (IP) was performed with
anti-FLAG antibodies followed by Western blot analysis with anti-FLAG
antibodies (B) to indicate immunoprecipitation of FRNH and with
anticore antibodies (C) to demonstrate coprecipitation of core. Core
interacts with a minimal RNase H domain extending from amino acids 680 to 780.
|
|
| |
DISCUSSION |
In this study, we described a model system for the analysis of
core-Pol interactions to begin to define the requirements of these
interactions in HBV encapsidation and replication. Core-Pol interaction
was observed in insect cells coinfected with baculoviruses expressing
core and Pol, as well as in the Huh7 liver cell line coinfected with
vaccinia virus core and Pol. The results indicate the occurrence of a
protein-protein interaction involving Pol and core that was not
dependent on an epsilon stem-loop sequence and was not disrupted after
treatment with RNase. In addition, core interacts with at least three
sites on Pol, within the TP, RT, and RNase H domains. One binding site
was detected within the amino terminus of the TP domain. Binding was
also observed with individual fragments spanning amino acids 176 to 550 of the RT polypeptides and amino acids 680 to 780 of the RNase H domain (Fig. 14). Interaction of core with the
RNase H domain could conceivably be involved in encapsidation, since
point mutations in the RNase H domain disrupt packaging (1, 5, 6,
13).
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|
FIG. 14.
Map summarizing core binding sites on Pol. FPL-pol
depicts the structure of the WT Pol construct; core binding sites on
amino- and carboxy-terminal deletion mutants of TP and RT are
illustrated below the diagram. The shaded areas represent the minimal
binding domains for each series. TPn, amino-terminal deletions of TP;
TPc, carboxy-terminal deletions of TP. The TP deletions share a common
area from amino acids 60 to 100, indicating the mapping of a common
binding site or possibly two binding sites, one in the amino-terminal
domain and one in the carboxy-terminal domain. RTn, amino-terminal
deletions of RT; RTc, carboxy-terminal deletions of RT. The RT
deletions share a common area from amino acids 400 to 550, which again
indicates the mapping of either a common core binding site or at least
two separate binding sites. RNH, carboxy-truncated RNase H domain. Core
binds to a minimal RNase H domain spanning from amino acids 680 to
780.
|
|
Sucrose gradient analysis revealed that Pol exists in a complex with
capsid particles, suggesting either that the core-Pol interaction
occurs between Pol and capsid particles or that Pol interacts with a
core monomer/dimer which is subsequently incorporated into a newly
formed capsid particle. Two lines of evidence support Pol interaction
with capsid particles. Core protein in the monomer/dimer fraction of
sucrose gradients did not coprecipitate with Pol, while interaction was
observed between Pol and capsid particles. Moreover, the analysis of a
large panel of core mutants suggested that capsid formation was an
essential attribute of core for interaction with Pol. The results
indicate that at least the FLAG epitope was exposed on the exterior of
the particle. Although during replication Pol would be expected to
reside on the interior of the particle, this model system could be
detecting a trapped intermediate in the encapsidation process. The
possibility that the Pol-epsilon RNP complex interacts with a
precapid-like particle during encapsidation has not been formally excluded.
At this time, we are unable to form core-Pol complexes using purified
proteins from baculovirus constructs or by the mixing of cell lysates
containing core and Pol. A number of factors could contribute to the
requirement for coexpression. Pol may interact in a nascent form before
complete folding has occurred. This is not likely to be the case for
core, since it would imply interaction at the monomer/dimer level.
Alternatively, host factors may be involved in the conformational
requirements for interaction or more directly in a mechanism supporting
initial contact. The role of Hsp90 in Pol-epsilon interaction has been
demonstrated in the DHBV system. In DHBV, RNP formation depends on
cellular factors that include Hsp90 and the chaperone partner p23,
which are incorporated into the viral nucleocapsid (15). The
requirement of cellular factors for core-Pol interactions was not
explored in this study.
Delineation of the steps in HBV replication represented by the core-Pol
interaction examined in this study is difficult in the absence of an in
vitro encapsidation and genome replication system. This study may
represent one step in the development of such a system. Core-Pol
interactions could play a role in multiple steps in HBV replication.
Encapsidation of the pregenomic RNA may require direct core-Pol
interaction even though the encapsidation substrate is an epsilon-Pol
RNP complex. The role of epsilon in this process could be to induce a
proper Pol conformation for interaction with core. Studies with DHBV
Pol support the contention that epsilon induces a conformational change
in Pol that is required for protein priming (40). The fact
that core-Pol interaction in insect cells was not dependent on epsilon
does not imply that this interaction is not essential for packaging.
Overproduction of Pol in insect cells may result in Pol polypeptides
with a variety of conformations, some of which may mimic the
conformation induced by epsilon, perhaps by interaction with cellular
RNAs with epsilon-like properties. Evidence for this also comes from
our studies on in vitro nucleotide priming with HBV Pol from insect
cells. With full-length Pol this event appears to be independent of
epsilon, although an RNA template is required (24). Epsilon
is required for the transcomplementation of nucleotide priming between
independently expressed TP and RT in insect cells (25). In
this instance, epsilon may serve to correctly align the interacting TP
and RT polypeptides and induce a conformation permissive for priming. Together, these studies and the observation that Pol cannot be encapsidated in the absence of epsilon suggest that one of the primary
roles of epsilon may be to induce a permissive conformation on Pol for
priming activity and interaction with core.
Core-Pol interactions are probably essential in genome replication
beyond the encapsidation step. Evidence for a continued interaction of
core and Pol during genome replication can be extrapolated from
mutagenesis studies on core. The deletion of amino acids from the
carboxy terminus of core results in a progressive deficiency in
completion of HBV genome replication. Previous work with these core
deletion mutants revealed that the deletion of carboxy-terminal amino
acids from core resulted in the progressive loss of DNA synthesis and
RNA packaging. Deletion to amino acid 163 resulted in the formation of
mutant capsids that were defective in DNA synthesis. Core proteins with
further deletion to amino acid 144, although defective for RNA
packaging, formed capsid particles, as shown by sucrose gradient
analysis (3). In our present study, all of the
capsid-forming deletion mutants except Cd148 coimmunoprecipitated with
the TP and RT domains of Pol. Further deletion of core to amino acids
135 and 112 resulted in a failure to form capsid particles and an
inability to coprecipitate with TP or RT. The results suggest that
although required, capsid formation is not sufficient for core-Pol interactions.
The formation of capsid-like particles was again revealed to be
necessary for interaction with Pol in the analysis of core insertion
mutants. Ci11, Ci36, Ci126, and Ci131 are the four core insertion
mutants that do not readily form capsids, and each of them failed to
coprecipitate with TP and RT. The capsid-forming mutant Ci44
coprecipitated with TP but failed to coprecipitate with RT. These
results indicate that the TP and RT domains of Pol have different
requirements for interacting with core. The differences in binding
activities between Ci44 and Ci46 suggest that subtle differences in
core influence RT recognition. Previous studies that analyzed capsid
formation in these mutants also examined the influence of the
insertions on RNA encapsidation and genome replication (4).
The core mutants Ci44 and Cp96 encapsidate WT levels of pregenomic RNA
and support reduced levels of both plus-strand and minus-strand DNA
synthesis. The core insertion mutants Ci46 and to a small degree Ci69
encapsidate low levels of pregenomic RNA, and the core mutants Ci67 and
Ci89 are deficient in encapsidation (4). All of these
capsid-forming core mutants interact with TP, and all but Ci44 interact
with RT. These results indicate that meeting the requirement for at
least one core-Pol interactive site is not sufficient for encapsidation
and certainly does not guarantee the formation of a
replication-competent particle. The results suggest that core-Pol
associations are essential for encapsidation and genomic replication,
yet the assembly of a replication-competent particle is considerably
complex, and the requirement for multiple interactions is evident.
| |
ACKNOWLEDGMENT |
This work was supported by grant CA53246 from the National
Institutes of Health.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Virology and Immunology, Southwest Regional Primate Research Center, Southwest Foundation for Biomedical Research, 7620 N.W. Loop 410, San
Antonio, TX 78227. Phone: (210) 258-9445. Fax: (210) 670-3329. E-mail:
rlanford{at}icarus.sfbr.org.
| |
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Journal of Virology, December 2000, p. 11479-11489, Vol. 74, No. 24
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Top
Abstract
Introduction
