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Previous Article | Next Article 
Mol Cell Biol, April 1998, p. 1919-1926, Vol. 18, No. 4
0270-7306/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Hepatitis Delta Virus RNA Editing Is Highly Specific for the
Amber/W Site and Is Suppressed by Hepatitis Delta
Antigen
Andrew G.
Polson,1,
Herbert L.
Ley III,1
Brenda L.
Bass,1 and
John L.
Casey2,*
Department of Biochemistry and Howard Hughes
Medical Institute, University of Utah, Salt Lake City, Utah
84132,1 and
Division of Molecular
Virology and Immunology, Georgetown University Medical Center,
Rockville, Maryland 208522
Received 27 October 1997/Returned for modification 10 December
1997/Accepted 24 December 1997
 |
ABSTRACT |
RNA editing at adenosine 1012 (amber/W site) in the antigenomic RNA
of hepatitis delta virus (HDV) allows two essential forms of the viral
protein, hepatitis delta antigen (HDAg), to be synthesized from a
single open reading frame. Editing at the amber/W site is thought to be
catalyzed by one of the cellular enzymes known as adenosine deaminases
that act on RNA (ADARs). In vitro, the enzymes ADAR1 and ADAR2
deaminate adenosines within many different sequences of
base-paired RNA. Since promiscuous deamination could compromise the
viability of HDV, we wondered if additional deamination events occurred
within the highly base paired HDV RNA. By sequencing cDNAs derived from
HDV RNA from transfected Huh-7 cells, we determined that the RNA was
not extensively modified at other adenosines. Approximately 0.16 to
0.32 adenosines were modified per antigenome during 6 to 13 days posttransfection. Interestingly, all observed non-amber/W
adenosine modifications, which occurred mostly at positions that are
highly conserved among naturally occurring HDV isolates, were found in
RNAs that were also modified at the amber/W site. Such coordinate
modification likely limits potential deleterious effects of promiscuous
editing. Neither viral replication nor HDAg was required for the highly
specific editing observed in cells. However, HDAg was found to suppress
editing at the amber/W site when expressed at levels similar to those
found during HDV replication. These data suggest HDAg may regulate
amber/W site editing during virus replication.
| |
INTRODUCTION |
Hepatitis delta virus (HDV) is a
subviral human pathogen that increases the risk of severe liver disease
in those infected with its helper, hepatitis B virus (34).
The HDV genome is an ~1,680-nucleotide (nt) circular RNA that
replicates through a circular RNA intermediate, the antigenome
(21). Both the genome and antigenome possess
extensive intramolecular complementarity and are predicted to
form rod-shaped structures in which about 70% of the nucleotides are
base paired (39).
HDV produces two forms of the sole viral protein, hepatitis delta
antigen (HDAg) (4), and both are translated from a single mRNA that is transcribed from the genomic RNA (16, 18, 40). The shorter form, HDAg-S, is required for RNA replication, while the
longer form, HDAg-L, inhibits replication but is required for packaging
the viral RNA with the envelope of hepatitis B surface antigen
(19, 35, 42). The virus uses adenosine-to-inosine RNA
editing activity of the host cell to produce HDAg-S and HDAg-L from the
same open reading frame (6, 25). The editing does not occur
on the mRNA directly but on adenosine 1012 of the antigenome (9,
32). The nucleotide change is subsequently passed to the genome
during replication and to the mRNA during transcription. The ultimate
effect is the conversion of the UAG amber termination codon of HDAg-S
to a UGG tryptophan codon required to synthesize the slightly longer
HDAg-L; because of the codon change produced by this editing event, the
editing site is called the amber/W site (32).
We previously showed that double-stranded RNA (dsRNA) adenosine
deaminase (ADAR1 [2]), purified from Xenopus
laevis, can edit the amber/W site of HDV RNA in vitro
(32). This enzyme converts adenosine to inosine in dsRNA (or
RNA that is largely double stranded) by deamination (reviewed in
reference 1). Editing at the HDV RNA amber/W site is
affected identically by site-directed mutations in the base-paired
structure around the amber/W site whether analyzed in cells or in vitro
with purified Xenopus ADAR1 (32). Thus, ADAR1, or
a closely related enzyme such as ADAR2 (formerly called RED-1
[26]), is thought to catalyze HDV RNA editing in vivo.
In vitro studies using synthetic substrates of ADAR1 (i.e., dsRNA) show
that as many as 50% of the adenosines in a single RNA can be
deaminated (1). However, the enzyme does not deaminate adenosine targets entirely randomly but rather exhibits
deamination specificity, which is described by using the terms
"preferences" and "selectivity" (31). ADAR1 shows
preferences for certain adenosines, and the total number of deamination
events in a single RNA molecule, or selectivity, varies for different
substrates. The preference for editing at the HDV amber/W site and the
selectivity that occurs on the HDV antigenome are likely to have
important consequences for virus viability, particularly because
sequence changes are passed to the genome. Excessive editing at the
amber/W site would result in reduced levels of RNA replication and
reduced production of viable virions because edited antigenomes encode HDAg-L, which inhibits RNA replication. Similarly, the amber/W adenosine would need to be a highly preferred deamination site compared
to other adenosines, and the reaction would need to be very selective
since promiscuous deamination could change the coding sequence in
deleterious ways or alter nucleotide sequences required for other viral
functions such as replication (3) or ribozyme activity
(30).
Here we investigate the specificity of HDV editing as it occurs in
transfected cells expressing HDV RNAs. We found that editing was very
specific for the amber/W site and that neither virus replication
nor HDAg was required for the high specificity. However, importantly,
we observed that HDAg was able to suppress the extent of editing that
occurred at the amber/W site and thus could play a role in
regulating the extent of editing during HDV replication.
| |
MATERIALS AND METHODS |
Plasmids.
Construct pHDVx1.2-R, used for expression of
replicating HDV RNA in transfected cells, was previously described as
pCMV3-DC1x1.2 (9). Plasmid pHDV
x1-NR, used for expression
of nonreplicating antigenomic HDV RNA in transfected cells, was created
by excising the 1,173-bp XbaI fragment containing a
monomeric unit of HDV, less the deleted ApaI region, from
pCMV3-DC-Apax1.2 (9). This fragment was inserted in the
XbaI site of the expression vector pCMV-MCS3 (9)
to generate pCMV-Apax1 (A), in which the cytomegalovirus (CMV)
promoter is oriented to produce antigenomic-sense HDV RNA in
transfected cells. The polyadenylation signal sequence was changed from
AATAAA to AATAG by PCR site-directed mutagenesis; the 181-bp SalI-XbaI fragment containing this
mutation replaced the corresponding fragment of pCMV-Apax1(A), which
had been cut with SalI and partially digested with
XbaI, to yield pHDVx1-NR. The disruption of the
polyadenylation signal sequence was found to increase amber/W
editing about twofold (data not shown). The sequence of the cloned
fragment in pHDVx1-NR was obtained by cycle sequencing (Life
Technologies, Grand Island, N.Y.) and verified both the presence of the
desired site-directed mutation and the absence of additional mutations.
The HDAg-S expression plasmid pCMV-AgS was created as follows. The
785-bp HindIII-XbaI fragment from pGDC-1,
which contains the HDAg coding sequences and the polyadenylation site,
was inserted between the HindIII and XbaI
sites of the expression vector pcDNAIneo (Invitrogen, San Diego,
Calif.) to yield pcDNAneoAgS. From this plasmid, the 1,557-bp
MluI-XbaI fragment containing the CMV promoter and HDV sequences was inserted between the MluI and
XbaI sites of the vector pGEM-7Zf(+) (Promega, Madison,
Wis.) to yield pCMV-AgS.
The expression plasmid pCMV-AgS(fs) is the same as pCMV-AgS except that
it contains a stop codon and frameshift at codon 7 in the HDAg coding
region (5). It was created by exchanging the
HindIII-PstI fragment of pHDV · I(+)Ag(
) (5) for that of pCMV-AgS. The expression
plasmid pCMV-AgSStuSma contains an in-frame deletion of nt 1110 to
1334 within the HDAg coding region. It was created by StuI
and SmaI digestion of pCMV-AgS, followed by ligation.
Transfections.
Human Huh7 hepatoma cells were cultured and
transfected by the calcium phosphate method as described previously
(6). Transfections were done in duplicate or triplicate, as
indicated. Where appropriate, the total amount of DNA in the calcium
phosphate precipitate was adjusted to 5.5 µg by addition of the
plasmid vector pCMV-MCS3. RNAs were prepared from cells harvested at
indicated times as described previously (6, 9) except that
proteinase K (1 mg/ml) was included in the lysis buffer for the
transfection experiments shown in Fig. 3 to 5.
Analysis of RNA editing.
Editing assays were performed as
described previously (9, 32). Briefly, RNA samples were
treated with DNase and then subjected to reverse transcription-PCR
(RT-PCR) amplification. Primers were 5414 and 5415 (9) or
7646 (5'-GGAGGTTGGGCCCGAAC-3') and 7647 (5'-TGTGAGTGGAAACCCGCCTA-3'), as indicated. PCR products were analyzed for amber/W editing by single-cycle labeling with [
-32P]dCTP followed by NcoI or
StyI restriction digestion as described previously (9,
32). Amber/W editing was indicated by the appearance of an
NcoI or StyI restriction site in the
amplification product. The effectiveness of the DNase treatment was
verified by the absence of PCR products after amplification without
prior reverse transcription. PCR products obtained without prior DNase treatment and without a prior reverse transcription reaction did not
yield StyI digestion fragments related to editing. Editing was quantified by electrophoresis followed by radioanalytic imaging (Ambis [San Diego, Calif.] imager or InstantImager [Packard
Instruments, Meriden, Conn.]).
Cloning and sequencing of PCR products.
RNA was reverse
transcribed with Superscript II (100 U; Life Technologies) or Moloney
murine leukemia virus reverse transcriptase (100 U; Life Technologies)
in 10-µl reactions containing 1× forward reaction buffer (supplied
by the manufacturer), 2 nmol of random hexamer, 1 mM
deoxynucleoside triphosphates, and 10 U of RNasin (Promega). Reaction
mixtures were incubated at 37°C for 15 min and then 42°C for 15 min. cDNA products were then amplified with Pfu polymerase
(Stratagene, La Jolla, Calif.). Forty microliters of a PCR master mix,
containing 1.25 U of Pfu DNA polymerase (Stratagene), 1×
Pfu polymerase buffer (supplied by the manufacturer), and 25 pmol of primers, was added to the 10 µl of reverse transcription reaction mixture. cDNA was amplified for 25 or 30 cycles of 1 min at
94°C, 1 min at 55°C, and 1 min at 72°C. Primers were 5414 and
5415 (9). PCR products were cloned with a pCR-Script kit (Stratagene). Barrier pipette tips were used to set up all reactions, and standard precautions were taken to minimize potential contamination of samples prior to PCR analysis (20). Control reactions
lacking reverse transcriptase or RNA were performed to ensure that the reactions were not contaminated.
For each experiment, multiple clones were obtained from independent
amplification reactions from different RNA samples. Both strands of
cloned PCR products were sequenced by the dye-terminator sequencing
system on Applied Biosystems 373A DNA sequencers at the University of
Utah Health Sciences Sequencing Facility. Sequence changes were
considered bona fide only if observed on both strands.
Northern blot analysis of HDV RNA.
RNA was electrophoresed
through 1.5% agarose gels containing 2.2 M formaldehyde, transferred
to positively charge nylon membranes, and hybridized with a
genomic-sense 32P-labeled probe as described previously
(10); the hybridization temperature was 60°C, and the
washing temperature was 70°C. The integrity of the RNA samples and
equivalent loading were assessed by visualization of RNA bands after
staining gels with ethidium bromide. Relative levels of HDV antigenomic
RNA were determined by radioanalytic scanning of blots with a Packard
InstantImager.
Immunoblot analysis.
Cell lysates were obtained by treatment
with 2% sodium dodecyl sulfate (SDS)-0.2 M Tris-HCl (pH 7.5)-1 mM
EDTA and analyzed for HDAg by SDS-polyacrylamide gel electrophoresis
(PAGE) in 12% acrylamide gels and immunoblotting with human anti-HDAg
as described previously (4). Relative HDAg levels were
assessed by radioanalytic scanning with a Packard InstantImager.
| |
RESULTS |
We previously showed that the amber/W site in HDV antigenomic
RNA can be edited in vitro by purified Xenopus ADAR1
(32). Editing was highly specific for the amber/W site:
under conditions that produced 16% ± 1% editing at
amber/W, the total amount of adenosine conversion was 0.81%
among all 340 adenosines in the RNA (32). This value
is much lower than the 50 to 60% deamination of adenosines typically
observed in dsRNA substrates under similar reaction conditions.
Nevertheless, 0.81% of 340 adenosines amounts to 2.7 A-to-I
conversions per antigenome (32); this level of deamination
could compromise the viability of the virus. We therefore investigated
the specificity of editing in cells transfected with either replicating
or nonreplicating HDV cDNA constructs.
Editing specificity in replicating HDV RNA in cells.
To
examine the specificity of HDV RNA editing occurring in cells, human
Huh-7 hepatoma cells were transfected in triplicate with the construct
pHDVx1.2-R, which produces replicating HDV RNA (Fig.
1 and reference 6).
Cells transfected with replication-competent HDV cDNA
constructs produce replicating HDV RNA in which editing levels increase
to a maximum of 20 to 35% by 12 to 15 days posttransfection (5,
6, 43). RNA was harvested 13 days posttransfection and analyzed
for editing at the amber/W site by StyI restriction (editing at the amber/W site of the HDV antigenomic RNA creates a
StyI restriction site in the corresponding cDNA [6,
32]) and by sequencing 84 cDNA clones from three separate
amplification PCRs from different RNA samples. The sequenced region was
a 358-nt segment corresponding to the C-terminal half of the
HDAg-coding sequence (Fig. 1, positions 907 to 1264, numbered according
to the genomic strand [39]) that includes the
amber/W site (1012) and that has been used extensively in
phylogenetic analyses of HDV isolates (7, 28, 37). This
region accounts for 21% of the entire antigenome and contains 77 adenosines.
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FIG. 1.
(A) Schematic diagram of HDV cDNA constructs, RNAs, and
regions amplified by the PCR. Left: thick straight bar, HDV cDNA; thin
line, plasmid sequences; dashed line pHDVx1-NR, sequences deleted
between ApaI sites (9). Direction of
transcription initiated by the CMV promoter is indicated by arrows.
Right: oval shapes with heavy lines, expected HDV RNA species; (+),
antigenomic sense; (), genomic sense. The location of the amber/W
site is indicated by an asterisk; the genomic and antigenomic ribozyme
cleavage sites (38, 41) are indicated by solid and open
triangles, respectively. Small open boxes indicate locations of
wild-type (pHDVx1.2-R) and mutated (pHDVx1-NR) polyadenylation
sites. Solid bars indicate expected PCR products; arrows mark primers A
(5415), B (5414), C (7646), and D (7647). Primers 7646 and 7647 correspond to sequences present only in the RNA derived from the
plasmid pHDVx1-NR. There is a single StyI site (indicated
in parentheses) in cDNAs amplified with primers 5414 and 5415 and
derived from edited RNA. Primers 7646 and 7647 yield cDNAs with the
same editing-sensitive site, plus an existing site that is unaffected
by editing. Nonreplicating RNA is produced in cells transfected with
the deletion construct pHDVx1-NR, which contains an ~514-nt
internal deletion and a site-directed mutation at the polyadenylation
signal site. The region to be deleted is indicated by an open segment
for construct pHDVx1.2-R and its derived RNAs and by a dashed line for
the construct pHDVx1-NR. Drawings are not necessarily to scale.
Horizontal gray arrows indicate transcription of RNAs from plasmid DNA
templates; vertical gray arrows indicate RNA template-driven
transcription occurring during HDV RNA replication. (B) Sequence of the
358-nt region analyzed by cloning and sequencing after amplification
with primers 5414 and 5415. Sequence shown is antigenomic sense;
numbering corresponds to the genomic RNA (39). The
amber/W site is indicated by an asterisk.
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Sequence analysis indicated that editing of replicating RNAs in cells
was highly specific. In good agreement with the amount of editing
(25%) determined by restriction digestion assays on the RNA,
24 of 84 clones (29%) contained G at the amber/W site. However, of the 6,384 non-amber/W adenosines sequenced,
only three A
G transitions (0.05%) were observed (Table
1, replicating; Fig.
2A). Amber/W editing accounted for at
least 89% of all AG changes on the replicating RNA in the 358-nt
region analyzed (Table 1). Extrapolation of the average number
of non-amber/W AG changes over the entire antigenome indicated
that, on average, only 0.16 such modifications occurred per molecule
(Table 1). Thus, editing of replicating HDV RNA in cells exhibits
considerably more specificity than that observed upon incubation of HDV
RNA with purified Xenopus ADAR1 in vitro (between 1.6 and
2.7 non-amber/W changes per antigenome [32, 33]).
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FIG. 2.
The percentage of HDV cDNA clones with AG transitions
at specific sites within the region from nt 907 to 1264 is plotted for
cDNA populations derived from replicating or nonreplicating HDV RNAs.
cDNA populations were derived from replicating HDV RNA harvested 13 days after Huh-7 cells were transfected with plasmid pHDVx1.2-R (84 clones) (A) and nonreplicating HDV RNA harvested 6 days after Huh-7
cells were transfected with the nonreplicating HDV RNA expression
plasmid pHDVx1-NR (97 clones) (B). Sequence numbering refers to the
genomic strand (39). Numbers in italics indicate sequence
positions that exhibited AG transitions.
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Clones from replicating HDV RNA also exhibited nine additional changes
other than AG, but no insertions or deletions. Because the frequency
of these non-AG changes (0.03%) was not much greater than the
misincorporation rate of Pfu polymerase, it is not certain whether these occurred in the cells during HDV replication or during
the PCR amplification, particularly as none of these changes appeared
in more than one clone. However, it is worth noting that among these
nine additional modifications were four UC transitions (in the
antigenomic sequence) that could result from adenosine deaminations
that occurred on the genomic RNA, because cells transfected with the
replicating construct pHDVx1.2-R contained both genomic and antigenomic
HDV RNA.
Highly specific editing observed in cells does not require HDAg or
viral replication.
We considered the possibility that HDV itself
was responsible for the high specificity of editing observed in cells.
For example, it seemed possible that spurious modification was
prevented in cells by the viral protein, HDAg, or that some aspect of
the replication process could select against non-amber/W
modifications. To determine whether HDV RNA replication or the presence
of the viral protein was required for the highly specific amber/W
editing observed in replicating RNAs in cells, Huh-7 cells were
transfected in triplicate with the nonreplicating HDV antigenomic RNA
expression construct pHDVx1-NR. This construct lacks a large portion
of the genome that is essential for replication and HDAg expression (Fig. 1) (22); thus, transfected cells expressed only
nonreplicating antigenomic HDV RNA (data not shown), and no HDAg was
detectable (see Fig. 4B, lane 6).
HDV RNA was harvested from Huh-7 cells 6 days after transfection with
the nonreplicating HDV RNA expression construct pHDVx1-NR. RNAs were
harvested earlier than in the comparable experiment with replicating
RNAs because we sought to compare editing specificity in replicating
and nonreplicating RNAs under conditions in which the amber/W site
was edited to similar extents, and previous experiments had indicated
that editing occurs more rapidly in the nonreplicating RNA expressed
from pHDVx1-NR (5). Sequence analysis indicated that 35 of 97 cDNA clones (36%) were from RNAs that had been edited at the
amber/W site. This value agreed with the amount of editing (35%)
determined by the restriction enzyme digestion assay and was only
slightly higher than the amount of editing observed 13 days
posttransfection in cells transfected with the replicating HDV RNA
expression construct pHDVx1.2-R. In the entire population of 97 clones, only seven AG changes were detected at sites other than
amber/W, nearly as few as in the replicating RNA (Fig. 2B; Table 1,
nonreplicating). Editing at the amber/W site accounted for 83% of
all AG transitions. Extrapolating the average number of AG
changes observed outside of the amber/W site over the entire antigenome showed an average of 0.32 such modifications per molecule (Table 1). Thus, in cells, the specificity of editing was very similar
for the nonreplicating and replicating HDV RNAs. This result suggests
that neither HDV RNA replication nor the presence of HDAg nor selective
pressure against genomes deaminated at adenosines essential for RNA
replication was responsible for the high specificity of editing that
occurred on replicating RNA in cells.
Possibly, some of the non-amber/W AG transitions observed in
cDNAs derived from HDV RNA in cells were due to processes other than
deamination reactions; for example, some changes could have been due to
transcription errors that occurred during viral replication or to
misincorporation errors that occurred during PCR amplification. However, the number of non-amber/W AG changes in both
transfection experiments combined (10) is greater than the
number of non AG changes (6, not including the 4 UC transitions),
which encompass 10 different nucleotide substitutions and were likely
due to such misincorporation errors (Table 1). Moreover, many of the
sites modified in the transfected cells were found to be modified under more than one set of experimental conditions. For example, position 973 was modified in a single clone from both replicating and nonreplicating RNAs in cells (Fig. 2); this site was also a preferred site for deamination in vitro by ADAR1 purified from Xenopus
(32, 33). In addition, the nonreplicating RNA yielded one
modification each at positions 1131 and 1175 (Fig. 2), both of which
were preferred sites for modification in vitro (32, 33).
Three of the seven AG transitions found in the 97 clones derived
from nonreplicating RNA transcribed in cells occurred at position 1005 (Fig. 2); although this site was not modified in other clones analyzed
in this study, it was modified in cDNAs derived from RNA of woodchucks
infected with HDV (27).
Although the total number of non-amber/W transitions introduced per
molecule is relatively low in transfected cells, comparison of these
changes with naturally occurring sequence variations suggests that many
of these changes could be deleterious. Of the seven non-amber/W
transitions observed in RNAs from transfected cells, four produced
nonconservative amino acid changes at positions that are more than 95%
conserved among naturally occurring HDV isolates (positions 973, 1034, 1175, and 1177 [28, 37]), one produced a silent codon
change in a fully conserved nucleotide position (position 1134 [28, 37]), and one introduced a naturally occurring
variation (position 1228 [28, 37]). Thus, it seems likely that some of these changes would have negative effects on the
ability of the virus to produce viable progeny. Remarkably, however,
all cDNA clones modified at non-amber/W adenosines were also
modified at amber/W (Table 2). This
association was statistically significant for both the replicating RNA
(P = 0.02) and the nonreplicating RNA
(P = 0.005). Because genomes modified at amber/W
are not viable (they encode HDAg-L, which inhibits replication),
coordinate modification of non-amber/W adenosines with amber/W
may limit the potentially deleterious effects of spurious editing on
virus viability.
HDAg inhibits amber/W editing.
Comparison of amber/W
editing in replicating and nonreplicating RNAs suggested that editing
occurred more efficiently in the absence of replication (Table 1). Not
only was the level of editing slightly higher for the nonreplicating
RNA, but the higher level was attained in less than half the time (6 days versus 13 days; see the legend to Fig. 2). Since HDAg was
expressed in cells transfected with the replication-competent HDV
construct pHDVx1.2-R but not in those transfected with the
nonreplicating construct pHDVx1-NR (see Fig. 4B, lanes 6 and 7),
it seemed possible that the lower amounts of editing in the replicating
cells was due to the presence of HDAg. This was a particularly
attractive hypothesis since HDAg has been shown to bind HDV RNA
(11, 12).
To determine whether HDAg could suppress editing, Huh-7 cells were
cotransfected with the nonreplicating RNA expression construct pHDVx1-NR and the HDAg expression construct pCMV-AgS, which directs expression of HDAg-S. In separate transfections, we included
either pCMV-AgS(fs), which produces no HDAg due to a frameshift-stop codon mutation introduced at codon 7 (8), or
pCMV-AgSStuSma, which produces HDAg from which 75 amino acids (aa),
including the RNA binding domain (23, 24), have been
deleted. Immunoblot analysis of lysates from transfected cells
indicated that the 75-aa deletion does not affect the level of HDAg
expression (data not shown). Although HDAg-S can support replication of
some HDV RNAs defective for HDAg synthesis, it does not support
replication of the construct used here because RNA elements
essential for replication have been deleted (22). To avoid
potential PCR amplification of unedited HDAg-encoding mRNA produced
from the HDAg expression vector, the primers used were specific for the
nonreplicating RNA derived from pHDVx1-NR (Fig. 1) and did not
amplify any detectable species from cells transfected with the HDAg
expression vector alone (data not shown).
Coexpression of HDAg with nonreplicating HDV antigenomic RNA strongly
suppressed editing at the amber/W site (Fig.
3). Cotransfection of the expression
plasmid for HDAg mRNA with a frameshift-stop codon mutation did not
suppress editing (Fig. 3). Thus, suppression required the expression of
HDAg and was not due to the mRNA alone, which could conceivably
interfere with the editing reaction by base pairing with the substrate.
No suppression of editing was observed when the construct
pCMV-AgSStuSma was cotransfected (Fig. 3), suggesting that the RNA
binding domain of HDAg was required for suppression.
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FIG. 3.
Effect of HDAg expression on editing at the amber/W
site. Human Huh-7 hepatoma cells were transfected with the
nonreplicating HDV RNA expression construct pHDVx1-NR plus
equivalent amounts of the following constructs: pCMV-MCS3, the
expression vector alone; pCMV-AgS, which expresses HDAg-S;
pCMV-AgS(fs), which expresses HDAg mRNA with a stop codon and
frameshift at codon 7; and pCMV-AgSStuSma, which expresses HDAg
containing an internal deletion. All cells were harvested 5 days
posttransfection and analyzed for editing at the amber/W site by
the appearance of a StyI restriction site (9,
32). The autoradiogram shows 32P-labeled RT-PCR
products, amplified with primers 7646 and 7647, uncut () or cut (+)
with StyI. PCR products contained an additional
StyI site that was not affected by editing (Fig. 1).
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To determine whether the suppression of amber/W editing by HDAg
might be biologically significant, Huh-7 cells were cotransfected with
the nonreplicating RNA expression construct pHDVx1-NR along with
various amounts of the HDAg expression construct pCMV-AgS. For
comparison, Huh-7 cells were also transfected with the
replication-competent construct pHDVx1.2-R. The transfections were
repeated three times and produced essentially identical results
each time; the data shown in Fig.
4 & 5 are
representative.
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FIG. 4.
Concentration-dependent effect of HDAg expression on
editing at the amber/W site. Human Huh-7 hepatoma cells were
transfected with 5 µg of the nonreplicating HDV RNA expression
construct pHDVx1-NR plus different amounts of the HDAg expression
construct pCMV-AgS (NR; lanes 1 to 6) or 5 µg of the replicating
HDV RNA expression construct pHDVx1.2-R (R; lanes 7). The amounts of
pCMV-AgS cotransfected were as follows: lanes 1, 0.2 µg; lanes 2, 0.05 µg; lanes 3, 0.01 µg; lanes 4, 0.002 µg; and lanes 5, 0.0005 µg. All cells were harvested 5 days posttransfection and analyzed for
editing at the amber/W site as described for Fig. 3 (A) as well as
for HDAg expression levels (B). (A) 32P-labeled RT-PCR
products, uncut () or cut (+) with StyI. Lanes 1 to 6, PCR
amplification with primers 7646 and 7647; lanes 7, primers 5414 and
5415. PCR products shown in lanes 1 to 6 contained an additional
StyI site that was not affected by editing (Fig. 1 and 3).
(B) SDS-PAGE-immunoblot analysis of HDAg expression (see Materials and
Methods). The relative HDAg expression levels were determined by
radioanalytic imaging with a Packard InstantImager. The numerical value
indicated for lane 6 was obtained from a duplicate lane in the same gel
that was not next to the strong signal in lane 7.
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FIG. 5.
Changes in editing associated with altered HDAg levels
do not correlate with altered RNA levels. Cells were cotransfected with
various amounts of the HDAg expression construct pCMV-AgS and
either 5 µg (columns A) or 0.5 µg (columns B) of
the nonreplicating HDV RNA expression construct
pHDVx1-NR. Numbers 1 to 6 refer to the same amounts of
pCMV-AgS transfected as for Fig. 3. For each cotransfection,
levels of amber/W editing were determined (bar height). In
addition, cellular levels of HDV RNA were determined by radioanalytic
imaging with a Packard InstantImager of Northern blots hybridized with
genomic-sense HDV RNA; the number above each bar indicates the amount
of HDV antigenomic RNA relative to that in column 1A. Cell
transfection, RNA harvesting, and editing analysis were as for Fig.
3.
|
|
Analysis of amber/W editing 5 days posttransfection indicated that
editing levels were about eightfold lower in replicating RNAs than in
nonreplicating RNAs produced in the absence of HDAg (Fig. 4A, lanes 6 and 7). However, coexpression of HDAg with nonreplicating HDV RNA
strongly suppressed editing at amber/W, and the amount of
suppression increased with higher levels of HDAg expression (Fig. 4).
At the highest level of HDAg expression, amber/W editing was
10-fold lower than that observed in the absence of HDAg. For an amount
of HDAg expression similar to that in cells with replicating HDV RNA,
the levels of editing were similar for the replicating and
nonreplicating RNAs (Fig. 4A and B; compare lanes 1, 2, and 7),
suggesting that the observed inhibition of editing by HDAg is
biologically important.
HDAg has been shown to stabilize nonreplicating HDV RNA in transfected
cells (23). Indeed, for cells transfected with the nonreplicating construct pHDVx1-NR, HDV RNA levels were about 15-fold higher in the presence of the highest amount of HDAg (Fig. 5).
Because ADAR1 activity is inhibited in vitro by high levels of
substrate (15), we considered the possibility that the
observed inhibition of editing by HDAg was an indirect effect of the
stabilization of HDV RNA. To address the effect of RNA levels on
editing, cells were also cotransfected, in duplicate, with 10-fold less
of the nonreplicating HDV RNA expression plasmid pHDVx1-NR than was used in the studies presented in Fig. 4. Analysis of amber/W
editing by RT-PCR and StyI digestion, and of RNA levels by
blot hybridization, indicated that inhibition of editing by HDAg was
not related to high RNA levels (Fig. 5). Dramatically different levels
of amber/W editing were observed in cells with very similar amounts
of HDV RNA but different amounts of HDAg (Fig. 5, columns 1B and 6A). Indeed, in the absence of HDAg, cells expressing lower levels of HDV
RNA actually exhibited a slightly decreased level of amber/W editing (28% versus 41% [Fig. 5, column 6]).
| |
DISCUSSION |
We have investigated the specificity of HDV RNA editing by
sequencing cDNAs derived from transfected cells harboring either replicating or nonreplicating HDV RNA. Consistent with previous studies
performed in vitro with purified ADAR1 from Xenopus
(32), we found that the biologically significant amber/W
site was the preferred modification site. Editing at this site
accounted for 89% of all AG transitions observed in cDNA
populations derived from HDV RNA replicating in cells. Editing was
highly selective overall: very few AG transitions occurred at
non-amber/W adenosines, and the majority of cDNA clones contained
none. For example, under conditions where 29% of the cDNAs from
replicating RNA showed an AG change at the amber/W site, only
0.05% of all other adenosines showed AG transitions. By
extrapolating data obtained from the 358-nt region sequenced to the
entire 1,679-nt antigenome, we estimate that 0.16 of the 340 non-amber/W adenosines in each antigenomic RNA were deaminated
during 13 days posttransfection. The high specificity of editing
observed in vivo did not require viral replication or the viral
protein, HDAg, because editing of nonreplicating HDV antigenomes was
similarly selective.
The minimal number of AG changes, or high selectivity, observed on
single HDV cDNAs, both in vitro and in cells, is remarkable for several
reasons. First, data from in vitro studies of ADAR1, using completely
base paired, synthetic substrates, indicate that ~50% of the
adenosines can be deaminated in a molecule with a length comparable to
that of HDV RNA (29). Of course, the HDV antigenome differs
from the artificial substrates in that it is not completely base
paired. As proposed to explain the high selectivity observed for
editing of gluR-B mRNAs (17), it seems likely that the
numerous mismatches, bulges, and internal loops found in the HDV
structure are in part responsible for the high selectivity. Indeed,
editing of HDV antigenomic RNA with purified ADAR1 from Xenopus was also found to be highly selective (0.48%
non-amber/W adenosines converted versus 16% of amber/W
[32, 33]). Thus, the selectivity may be due in large
measure to interactions between the RNA and the deaminase.
The 358-nt region analyzed in this study is well conserved among HDV
genotype I isolates (28, 37). Of the seven adenosines (excluding amber/W) that were found modified among the 181 clones analyzed (Fig. 2), five are more than 95% conserved among
over 100 HDV genotype I isolates. The conservation suggests adenosines at these positions could be necessary for virus propagation and that
their deamination could interfere with the viral life cycle. Alternatively, it is also possible that low-level modification at some
sites serves an important function in the viral life cycle, similar to
what occurs at the amber/W site. The lack of substantial correlation between positions observed to be modified in this study and
those seen to vary among different isolates, or among those observed to
change during high-dose passage in infected woodchucks (27),
could indicate that adenosine deamination is not a predominant
mechanism for genetic drift of HDV. Given the high degree of sequence
conservation of many of the deamination sites, it is significant that
our data showed that modification of non-amber/W sites in vivo was
linked to modification at amber/W. All 10 adenosine conversions at
other positions occurred in RNAs that were also modified at amber/W
(Table 2). A similar, though weaker, linkage was observed for
modification of sites neighboring the Q/R site in gluR6 pre-mRNAs
(14).
When put in the context of the viral life cycle, the high degree of
specificity associated with HDV RNA editing, as well as the coordinate
modification of non-amber/W adenosines on RNAs also modified at
amber/W, makes biological sense. Sequence changes at
non-amber/W adenosines will be passed to the genome during HDV
replication. Promiscuous deamination of non-amber/W adenosines within the HDAg coding region could cause deleterious effects on
protein expression and function, or deamination within noncoding sequences could alter RNA secondary structures essential for
replication and/or packaging. Perhaps during the evolution of HDV there
has been selective pressure toward sequences and structures that are not optimal for deamination. The linkage of non-amber/W
modifications with amber/W site changes is significant because
genomes edited at amber/W produce only the long form of HDAg, which
inhibits RNA replication, and would not be able to subsequently infect other cells. Thus, the accumulation of additional modifications on
genomes edited at amber/W would not further limit the viability of
viral progeny.
One of the most interesting outcomes of our study is the observation
that HDAg can alter the extent of editing at the amber/W site or,
using the previously defined term (1, 31), the
preference for this site. Although there has been considerable
speculation that ADAR1 activity is regulated by accessory factors in
vivo and some evidence to support such a view (13, 36), our
result is the first example in which a specific factor has been
identified. Clearly, editing at the amber/W site must be regulated
in some manner since complete editing at this site would result in
viral genomes that could no longer produce HDAg-S, which is absolutely required for replication (19). The observed ability of HDAg to inhibit amber/W editing in a concentration-dependent manner suggests a role for HDAg in this regulation. Because HDAg can bind HDV
RNA (11, 12), and a 75-aa segment including the RNA binding
domain was required for the inhibitory effect (Fig. 3), it seems
possible that the inhibition could occur by direct steric interference
through binding at or near the amber/W site. Certainly our future
experiments will address this and related issues.
| |
ACKNOWLEDGMENTS |
This work was supported by funds to J.L.C. from NIAID
(contract NO1-AI-45179) and funds to B.L.B. from the National
Institutes of Health (grant GM 44073) and the David and Lucile Packard
Foundation. Oligodeoxyoligonucleotides were synthesized by the Utah
Cancer Center Protein/DNA core facility, supported by the National
Cancer Institute (grant 5 P30 CA42014). B.L.B. is a Howard Hughes
Medical Institute associate investigator.
We thank Thomas L. Brown for excellent technical assistance, R. Hough
and S. Hurst for providing purified ADAR1, and M. Robertson and E. Lawrence (Health Sciences Center Sequencing Facility) for their
extensive sequencing of numerous cDNA clones. We also appreciate the
helpful suggestions and discussions from the members of our research
groups.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Division of
Molecular Virology and Immunology, Georgetown University Medical
Center, 5640 Fishers Lane, Rockville, MD 20852. Phone: (301) 881-2676. Fax: (301) 881-0810. E-mail: caseyj{at}medlib.georgetown.edu.
Present address: Department of Microbiology, University of San
Francisco Medical Center, San Francisco, CA 94143-0414.
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Top
Abstract
Introduction
