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Previous Article | Next Article 
Antimicrobial Agents and Chemotherapy, August 1999, p. 1947-1954, Vol. 43, No. 8
0066-4804/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Emergence of Drug-Resistant Populations of
Woodchuck Hepatitis Virus in Woodchucks Treated with the Antiviral
Nucleoside Lamivudine
Tianlun
Zhou,1,2
Jeffry
Saputelli,1
Carol E.
Aldrich,1
Manon
Deslauriers,3
Lynn D.
Condreay,3 and
William
S.
Mason1,*
Fox Chase Cancer Center, Philadelphia,
Pennsylvania 191111; Biomedical Graduate
Studies, University of Pennsylvania, Philadelphia, Pennsylvania
191042; and Department of Virology,
Glaxo Wellcome, Inc., Research Triangle Park, North Carolina
277093
Received 1 February 1999/Returned for modification 31 March
1999/Accepted 24 May 1999
 |
ABSTRACT |
Lamivudine [(
)-
-L-2',3'-dideoxy-3'-thiacytidine]
reduces woodchuck hepatitis virus (WHV) titers in the sera of
chronically infected woodchucks by inhibiting viral DNA synthesis.
However, after 6 to 12 months, WHV titers begin to increase toward
pretreatment levels. Three WHV variants with mutations in the active
site of the DNA polymerase gene are present at this time (W. S. Mason et al., Virology 245:18-32, 1998). We have asked if these mutant viruses were responsible for the lamivudine resistance and if their
emergence caused an immediate rise in virus titers. Cell cultures
studies implied that the mutants were resistant to lamivudine. Emergence of mutant WHV was not always associated, however, with an
immediate rise in virus titers in the serum. One of the three types of
mutant viruses became prominent in serum up to 7 months before titers
in serum actually began to increase, at a time when wild-type virus was
still predominant in the liver. The two other mutants did not show this
behavior but were detected in serum and liver later, just at the time
that virus titers began to rise. A factor linking all three mutants was
that a similar duration of drug administration preceded the rise in
titers, irrespective of which mutant ultimately prevailed. A simple
explanation for these results is that the increase in virus titers
following emergence of drug-resistant mutants can occur only as the
preexisting wild-type virus is cleared from the hepatocyte population,
allowing spread of the mutants. Thus, prolonged suppression of virus
titers in the serum may sometimes be a measure of the stability of
hepatocyte infection rather than of a successful therapeutic outcome.
| |
INTRODUCTION |
Exposure to hepatitis B virus (HBV)
can lead to chronic infection, which is a cause of cirrhosis and liver
cancer. The treatment of chronic HBV infection to block this
progression is still in its infancy. Alpha interferon is the only drug
widely used to treat virus carriers, and the response rate is probably
about 20% (10, 21). Lamivudine
[()--L-2',3'-dideoxy-3'-thiacytidine], a nucleoside
analogue, has now been approved by the U.S. Food and Drug
Administration for the treatment of hepatitis B. The administration of
lamivudine induces a significant drop in the amount of virus in the
serum of most HBV carriers and, unlike alpha interferon, causes no
significant side effects in most patients. The emergence of
drug-resistant HBV may, unfortunately, begin after 6 to 12 months of
therapy (2-4, 9, 15, 19, 20, 25). As with human
immunodeficiency virus (23), mutations related to lamivudine
resistance are invariably mapped to the methionine residue in the YMDD
motif of the HBV polymerase active site (amino acid 552), with a switch
to YIDD or YVDD. The YVDD mutation has also been shown to confer
lamivudine resistance when it is introduced into duck HBV
(7). In addition, the change from YMDD to YVDD in HBV is
associated with an upstream amino acid replacement of leucine (amino
acid 528) with methionine (2, 19). This upstream change is
localized to the B region, a stretch of amino acids found in the active
site of many polymerases, including that of HBV and woodchuck hepatitis
virus (WHV) (Fig. 1). Moreover, resistance of HBV to famciclovir maps to the B region (3).
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FIG. 1.
Mutations in the B region of the WHV polymerase arise
during lamvidine therapy. (A) Amino acid changes. (B) Nucleotide
changes and cleavage sites for the three restriction endonucleases used
for genotyping of clones of PCR-amplified viral DNA. The sequence of
WHV, as reported by earlier investigators (5), is presented
in the top line of each panel. It should be noted that this polymerase
sequence is one amino acid longer than that reported by Kodama et al.
(14), as the result of an insertion at position 15 (see Fig.
4).
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We recently reported on the development of drug resistance in
WHV-infected woodchucks treated with lamivudine (17). The WHV genomes, present after virus titers had increased toward
pretreatment levels, had a normal YMDD motif. However, mutations in the
active site of the viral DNA polymerase were detected in the upstream B
region (Fig. 1). All mutants were altered at amino acid 566, which
corresponds to position 529 in HBV. One had an alanine-to-threonine mutation (type I variant), one had a mutation to valine (type II
variant), and the other had a mutation to serine (type III variant).
The nucleotide change that produces the alanine-to-threonine change in
polymerase also introduces a stop codon into the overlapping S gene,
potentially truncating 55 amino acids from the carboxy termini of the
three viral envelope proteins. The mutation to valine at position 566 occurred together with a leucine-to-methionine change at position 565 (HBV position 528). The mutation to serine at position 566 occurred
with a leucine-to-methionine change at position 565 and a
serine-to-asparagine change at position 570.
The present study was undertaken to address two issues. First, were
these mutant viruses responsible for the rise in virus titers seen in
virtually all woodchucks treated for up to a year with lamivudine?
Second, did the rise in virus titers coincide with the rapid spread of
a new drug-resistant strain of WHV through the liver? Alternatively,
was the spread of mutant virus retarded by the wild-type virus present
in hepatocytes when therapy was initiated, with the rise in titers
occurring only after a sufficient time for clearance of wild-type DNA?
We present evidence that the mutant viruses had a drug-resistant
polymerase and were probably responsible for the emergence of the
drug-resistant phenotype in vivo. Our data also indicated that at least
one of the three strains of lamivudine-resistant WHV could be present
months before virus titers increased. These data support the hypothesis
that wild-type virus infection of hepatocytes prevents emergence of drug resistance, as reflected by rising virus titers, until there is a
substantial depletion of wild-type covalently closed circular DNA
(cccDNA). A recent study on the appearance of drug-resistant strains of
HBV, in which mutant virus was present in the serum of patients 4 months prior to an increase in virus titers, points to the same
conclusion (4).
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MATERIALS AND METHODS |
Woodchucks.
Woodchucks (Marmota monax)
were housed in the laboratory animal facility of the Fox Chase Cancer
Center. The experiments with the woodchucks were reviewed and approved
by the Center's Institutional Animal Care and Use Committee.
Captive-born woodchucks 300, 302, and 315 were purchased from
Northeastern Wildlife (South Plymouth, N.Y.), and woodchucks 4960 and
4961, a gift of B. Tennant, were from the breeding colony at Cornell
University, Ithaca, N.Y. Chronic infection was achieved by neonatal
inoculation with serum from WHV-infected woodchucks. Lamivudine
treatment of woodchucks 300, 302, 315, and 4960 and placebo
administration to woodchuck 4961 were initiated when the animals were
13 to 16 months of age, as described previously (17). The
first three woodchucks received an initial dose of 40 mg per kg of body
weight, which was escalated to 200 mg per kg after 3 months, while the
last woodchuck was started on the dose of 200 mg per kg.
PCR amplification and direct sequencing of WHV DNA.
Serum
samples collected from each woodchuck were stored at 80°C. To
prepare virion DNA, 50 µl of woodchuck serum was layered on top of a
10 to 20% sucrose step gradient containing 0.15 M NaCl and 0.02 M
Tris-HCl (pH 7.5), and virus was pelleted by centrifugation for 3 h at 50,000 rpm in a Beckman SW-60 rotor. The virus was resuspended in
200 µl of 0.1 M NaCl-0.01 M Tris-HCl (pH 7.5)-0.01 M EDTA-0.2%
sodium dodecyl sulfate-1 mg of pronase per ml, followed by incubation
for 1 h at 37°C. The mixture was then extracted two times with
phenol-chloroform, and viral DNA was precipitated by the addition of 2 volumes of ethanol, with 10 µg of dextran used as the carrier. PCR
amplification was then carried out in a reaction volume of 50 µl with
KlenTaq polymerase (ClonTech Laboratories). The amplification
conditions included 1 min of denaturation at 94°C and 30 cycles of 1 min at 94°C, 1 min at 57°C, and 1 min at 72°C, followed by 4 min
at 72°C. The forward primer (5'-AGATTGGTGGTGCACTTCTCTCAG-3') spanned WHV nucleotides 385 to 408 (14). The reverse
primer (5'-CCACGGAATTGTCAGTGCCCAACA-3') spanned nucleotides
1474 to 1451. PCR products were purified with the QIAquick Kit (Qiagen,
Inc., Hilden, Germany), as recommended by the manufacturer. The
products were sequenced with 5'-GGATGTATCTGCGGCGTTT-3'
(nucleotides 510 to 528) as the sense primer and
5'-CCCAAATCAAGAAAAACAGAACA-3' (nucleotides 953 to 931) as
the antisense primer, respectively.
Proportions of wild-type and mutant viral DNA in serum and
liver.
Reconstruction experiments revealed that direct sequencing
of the PCR products could detect sequence variants that represented as
little as 10 to 20% of the major species. However, where more than one
minor variant is present, this approach cannot reveal whether minor
sequences changes are associated with one or more than one variant. To
obtain a truer representation of sequence variation, virion DNA
isolated from woodchuck serum that was collected at different time
points during lamivudine treatment was amplified by PCR with forward
primer 5'-GACATACCACGTGGTTTAGTTCCG-3' (nucleotides 8 to 31)
and reverse primer 5'-AGGGAGATCCGAGTCGTCTGA-3' (nucleotides 1664 to 1644). To estimate the proportions of the four different genetic variants of the B region of the viral polymerase (wild type and
type I, type II, and type III variants) the PCR products were purified
with the QIAquick Kit (Qiagen, Inc.) and were then cloned. Individual
recombinant clones were subjected to PCR. The forward primer had the
sequence 5'-TACCTATTAGTCCTGCTGCTGTGC-3' (nucleotides 536 to
560), and the reverse primer had the sequence 5'-GCCCCACCATTTTGTTTTATTGAC-3' (nucleotides 990 to 966). The
mutations in variants types I, II, and III change the pattern of
cleavage by HinfI, NlaIII, and SpeI,
respectively (Fig. 1). HinfI cuts only type I,
SpeI cuts the wild type and types I and II but not type III,
and NlaIII cuts types II and III but not the wild type or
type I. Therefore, digestion of the PCR product with these restriction
endonucleases, followed by agarose gel electrophoresis, was used to
determine the B-region genotype.
To determine the sequence of the B region of cccDNA extracted from
woodchuck liver biopsy specimens, PCR amplification, cloning, and
restriction digestions were carried out as described above. Prior to
PCR amplification, the cccDNA was purified as reported previously
(17) and was then subjected to alkaline extraction, as
described by Yang et al. (29).
Cloning of WHV cccDNA.
Liver biopsy samples were obtained
from woodchuck 302 before and during lamivudine therapy, and nucleic
acids enriched for cccDNA were extracted as described previously
(17). The cccDNA was then purified by agarose gel
electrophoresis (detection was by subsequent blot hybridization),
cleaved with EcoRI, and cloned into bacteriophage lambda
gt11 (Promega). (Only a single linear cleavage product was detected
after digestion of the cccDNA with EcoRI.) In some cases,
the viral DNA was then subcloned, after EcoRI digestion,
into pGEM-3Z, and the full sequence of the viral DNA was determined.
To compare the sequences of the DNA polymerase region of a large number
of individual phage lambda gt11 cccDNA clones, PCR amplification was
carried out, followed by sequencing of the PCR product.
Transfection of a human liver cell line, Huh7.
WHV
expression vectors in which pregenomic RNA is transcribed from the
cytomegalovirus immediate-early promoter (24) were used to
test the effects of different mutations of the B region of the DNA
polymerase on viral DNA synthesis in the presence and absence of
lamivudine. For the wild type, we used an infectious clone of WHV
(24), which was thought to be identical to the clone
originally sequenced by Kodama et al. (14). In preliminary studies, a number of nucleotide differences between this clone and the
published sequence were detected in the region under study. We
therefore determined the complete sequence of this WHV clone. The
predicted polymerase open reading frame (ORF) is shown in Fig. 4.
Mutations were introduced into the B region of the wild type through
site-directed mutagenesis by the PCR method of gene splicing by overlap
extension (11, 12). Design of the oligonucleotides for
introduction of mutations was based upon prior sequencing through this
region of the cloned DNA, which was carried out as described above. All
the constructs were sequenced. Ten micrograms of DNA was used to
transfect Huh7 cells, which were growing in 60-mm tissue culture
dishes, when the monolayers were about 70% confluent (26).
Huh7 cells were cultured in F-12 minimal essential medium at 37°C
with 5% CO2. To test for inhibition of viral DNA synthesis, lamivudine was added 24 h prior to transfection at a
concentration of 100 µM. Culture medium with or without lamivudine was changed every day.
At 5 days posttransfection the cell monolayers were rinsed with
phosphate-buffered saline and were stored at 80°C. For extraction of intermediates in viral DNA replication, the monolayers were thawed
by the addition of 1 ml of lysis buffer containing 0.01 M Tris-HCl (pH
8.0), 0.001 M EDTA, 1% (vol/vol) Nonidet P-40, 0.05 M NaCl, and 8%
(wt/vol) sucrose. The lysate was harvested and centrifuged at 11,000 × g for 2 min at 4°C, and the pellet was discarded. Ten
microliters of 1 M magnesium acetate, 10 µl of 10 mg of DNase I
(Boehringer) per ml, and 10 µl of 10 mg of microliters RNase A per ml
were added to the supernatant; and the mixture was incubated for 30 min
at 37°C. Following clarification by centrifugation at 11,000 × g for 4 min, polyethylene glycol, NaCl, and EDTA were added
to the supernatant to final concentrations of 6.5%, 0.35 M, and 0.01 M, respectively. The mixture was then placed on ice for 1 h, after
which the precipitate was collected by centrifugation at 11,000 × g. The pellet was then digested for 1 h at 37°C in
0.025 M Tris-HCl (pH 7.4)-0.01 M EDTA-0.1 M NaCl-0.5% (wt/vol)
sodium dodecyl sulfate-0.5 mg of pronase per ml. The DNA was then
extracted with a phenol-chloroform mixture (1:1) and was concentrated
by ethanol precipitation.
One-quarter of the DNA extracted from each tissue culture dish was
subjected to electrophoresis in a 1.5% agarose gel and was then
transferred to a nitrocellulose membrane for hybridization (27) with a 32P-labeled probe representing the
complete WHV genome. Following hybridization, bound radioactivity was
measured with a Fuji Image Analyzer. A full-length, linear, cloned
viral DNA served as an electrophoresis and hybridization standard.
Primary woodchuck hepatocyte cultures.
Primary hepatocytes
prepared from WHV-negative woodchuck liver were seeded onto 60-mm
tissue culture dishes coated with rat-tail collagen and were maintained
in serum-free medium at 37°C (1). Prior to seeding,
hepatocytes were partially purified by centrifugation through 90%
Percoll (Sigma) for 15 min at 1,500 rpm (18). To directly
evaluate the lamivudine-resistant properties of the WHV variants
present in woodchuck serum, 50 µl of woodchuck serum was used to
infect hepatocytes in the presence or absence of 500 µM lamivudine.
Medium was changed daily, and the cells were harvested at 16 days
postinfection. Intermediates in viral DNA replication were extracted
and analyzed by electrophoresis in 1.5% agarose gels, transfer to
nitrocellulose filters, and hybridization with a
32P-labeled WHV DNA probe (18).
| |
RESULTS |
Lamivudine resistance in woodchucks is due to the emergence of
mutant strains of WHV.
Treatment of woodchucks with lamivudine
leads to a transient suppression of virus titers. Within a year,
however, titers begin to rise toward pretreatment levels
(17). At this time, mutations are detected in the B region
of the viral DNA polymerase (Fig. 1) (17), suggesting that
resistance to therapy may be due to the emergence of drug-resistant
strains of WHV.
To directly test for lamivudine-resistant strains of WHV, we assayed
for inhibition of viral DNA synthesis following infection of primary
woodchuck hepatocyte cultures with serum-derived virus. For this
experiment, we analyzed virus collected before lamivudine therapy and
again when titers had increased after a period of suppression by lamivudine.
Lamivudine inhibited viral DNA replication (accumulation of viral DNA
replication intermediates, detected as the more rapidly migrating
species labeled SS [single stranded]) following infection with virus
collected before therapy, as shown in Fig.
2A for four different woodchucks. Sera
collected near the end of lamivudine therapy generally had a lower
titer and sometimes a lower specific infectivity in primary hepatocyte
cultures, and we were able to obtain results for only three of the four
lamivudine-treated woodchucks. Sera from these three woodchucks
contained lamivudine-resistant WHV (Fig. 2B). Thus, in these
woodchucks, the failure of lamivudine to continuously suppress virus
replication is apparently due to the eventual outgrowth of
lamivudine-resistant strains of WHV.
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FIG. 2.
Lamivudine (LAM) resistance of WHV in primary hepatocyte
cultures. Virus present in sera (50 µl) collected from four different
woodchucks (WC) prior to lamivudine therapy (A) or after the indicated
number of months of therapy (B) was tested for sensitivity to the drug.
Virion titers per milliliter of serum (A), as determined by Southern
blotting, were 8 × 109 (woodchuck 300), 8 × 109 (woodchuck 302), 8 × 109 (woodchuck
315), and 1.4 × 1010 (woodchuck 4960). Virion titers
per milliliter of serum (B) were 1.3 × 109 (woodchuck
4960, 10 months), 2 × 109 (woodchuck 315, 18 months),
<8 × 106 (woodchuck 315, 12 months), 2 × 109 (woodchuck 302, 17 months), 2 × 108
(woodchuck 302, 12 months), 5 × 108 (woodchuck 300, 12 months), and 3 × 107 (woodchuck 300, 5 months).
Lamivudine (500 µM) was added 1 day before infection and was
maintained in the culture medium until the cells were harvested at 16 days postinfection. DNA was extracted and assayed for WHV replication
intermediates by Southern blot analysis. Markers included a
32P-labeled HindIII digest of phage lambda
DNA and 75 pg of linear viral DNA (lane M). The viral DNA that migrated
between 4.4 and 2.3 kbp may be derived, in part, from the inoculum.
Therefore, the best indicator of virus DNA replication is the presence
of species (single-stranded [SS] DNA) that migrated faster than the
2.0-kbp marker (16). By this criterion, replication of
pretreatment virus was inhibited at least 40-fold. Replication of serum
from woodchucks 300 (12 months), 315 (18 months), and 4960 (10 months)
was inhibited approximately 2.5-, 2-, and 5-fold, respectively. cccDNA
formation (data not shown) in the absence of lamivudine was detected
only in cultures in which replicative intermediates were also detected
and were found to be present in proportion to the amount of replicating
DNA that accumulated in the cells. cccDNA formation was not inhibited
by lamivudine in cultures infected with drug-resistant WHV and was
inhibited between 3- and 30-fold in cultures infected with different
stocks of nonresistant virus. In the latter instance, the cccDNA was
presumably formed from infecting viral DNA, as no virus DNA replication
was detected.
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To obtain evidence that this might be the case for all of the
woodchucks and to facilitate a more detailed analysis of the emergence
of these lamivudine-resistant strains of WHV, we asked if the different
mutations that have been observed in the B region could produce
lamivudine resistance. If so, an analysis of virus genotypes could be
used to characterize the emergence of drug-resistant strains of WHV
during the course of therapy.
Site-directed mutagenesis was therefore used to introduce the type I,
II, and III mutations (Fig. 1) into a laboratory strain of WHV. The
wild-type DNA and the three different mutated viral DNAs were then used
to transfect Huh7 cells (28). Expression of the WHV
pregenome, which provides all the functions necessary for viral DNA
synthesis (13), was under control of the cytomegalovirus immediate-early promoter, as WHV transcription is inefficient in many
different liver cell lines (6). In the presence of lamivudine, accumulation of intermediates in the replication of wild-type WHV DNA was reduced to background levels (Fig.
3). In comparison, only a two- to
threefold reduction was observed after introduction of the type I and
II mutations into viral DNA, and a less than twofold reduction was
observed with the type III mutations. Thus, all three classes of
mutations produced resistance to lamivudine, implying that a direct
assay for these genotypes could be used to assess the emergence of
lamivudine-resistant WHV during the course of treatment. The results
also suggest that the type I and II mutants may replicate less
efficiently than the wild type; however, it is possible that other
sequence differences between mutants and wild types of natural isolates
may compensate for these differences.
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FIG. 3.
The type I, II, and III mutations of the pol
gene produce lamivudine (LAM) resistance. The type I, II, and III
mutations (Fig. 1) were introduced into cloned WHV DNA as described in
Materials and Methods. When present, lamivudine was added 24 h
prior to transfection with 10 µg of DNA. Intracellular viral DNAs
were harvested after 5 days and were subjected to Southern blot
analysis. Unlike the infection experiment, the most likely source of
nonreplicated viral DNA in this transfection experiment is small
fragments of plasmid DNA that survived the DNase I treatment that was
used during the isolation of viral particles. Therefore, partially
double-stranded WHV DNA is a more reliable indicator of virus DNA
replication in this experiment. PDS, partially double-stranded viral
DNA; SS, single-stranded viral DNA; WT, wild type. Markers included a
32P-labeled HindIII digest of phage lambda
DNA and 75 pg of linear viral DNA (lane M).
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Therefore, before proceeding with a more detailed genotype analysis, we
also carried out a preliminary study to determine if mutations outside
the B region might contribute to the acquisition of lamivudine
resistance. For this purpose, we focused on the type I mutant, which
was the most commonly observed type of mutant in the previous study
(17). cccDNA molecules present before therapy and after 12 and 18 months of lamivudine therapy were cloned from the liver of
woodchuck 302. The genotypes of the B region of 47 of these clones are
presented in Table 1. One clone with a
wild-type B region and three clones with a B-region mutation (type I)
were then fully sequenced. The predicted amino acid sequence of the
polymerase ORF is shown in Fig. 4. A
number of mutations that produced amino acid changes in addition to the
alanine-to-threonine change at position 566 (type I) were observed;
however, the only one that was found in all three of the clones with a
type I mutation was the histidine-to-tyrosine change at position 211. This site is part of the tether region that separates the upstream
protein that primes from the downstream active-site domains, and on
this basis alone it seemed unlikely to affect substrate specificity. Moreover, analyses of additional type I clones did not reveal a
complete correlation between this upstream mutation and the type I
mutation in the B region (Table 1). Thus, amino acid changes outside
the B region may contribute to the acquisition of lamivudine resistance
and/or to the efficiency of replication of mutant virus in vivo, but
these contributions do not appear to map to a unique site.
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FIG. 4.
Sequences of the polymerase ORF for four clones of
cccDNA isolated from woodchuck 302 (wc 302). Full-length viral DNA was
cloned from preparations of cccDNA prepared from the liver before
therapy and after 12 and 18 months of lamivudine treatment. The
complete sequence of each was determined and was used to predict the
amino acid sequence of the polymerase ORF. For comparison, two
sequences from GenBank are shown (whvref#1, accession no. M11082
[14]; whvref#2, accession no. M19183
[5]), together with the sequence determined for the
clone of WHV that is used in our laboratory. As shown, there were some
discrepancies between the sequence reported by Kodama et al.
(14) and the sequence of the laboratory strain of WHV DNA
that was used in the present study, although it was believed that the
strains were originally the same.
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Emergence of lamivudine-resistant strains of WHV is not associated
with an immediate rise in virus titers.
Having obtained evidence
that the B-region mutations were able to produce lamivudine-resistant
WHV, we determined the time course of appearance of mutant virus DNA in
the liver and serum. The primary goal of this analysis was to determine
the temporal relationship between the appearance of mutant virus in
serum and liver and the increase in virus titers that occurs during
prolonged lamivudine therapy.
A region of the polymerase active site that includes regions B and C
(Fig. 1) was amplified by PCR from virion DNA collected throughout the
course of drug therapy and was then sequenced. Results for four
woodchucks, woodchucks 300, 302, 315, and 4960 (also see Mason et al.
[17]), are summarized in Fig.
5 and Table 2. With woodchuck 300 the type I variant
was detected as early as 7 months before virus titers began to
increase, while the type II and III variants were first prevalent at
the time that the increase occurred. Similarly, for woodchuck 315, the
type I mutant was detected 7 months before an increase in titers, and a
shift to type II occurred at about the time that virus titers began to
rise. For the two other woodchucks (woodchucks 302 and 4960), a type I
mutant first became abundant in serum just about the time of the
increase (woodchuck 4960) or shortly thereafter (woodchuck 302) (Fig.
5). However, cloning of the PCR products revealed that a type II
variant was also abundant in the serum of woodchuck 4960 at the time
that virus titers rose (Table 2), a result that was not apparent by
direct sequencing of PCR-amplified viral DNA (Fig. 5). Likewise,
cloning and sequencing of PCR products revealed the type I mutation in
woodchuck 302 at 10 months, prior to the rise in virus titers (data not
shown). (Unless a minor species represented at least 10 to 20% of
viral DNA, it would not have contributed a detectable signal to the DNA
sequencing ladders.) Thus, a type I mutant could persist for at least 7 months without producing an increase in titers, and in three of four
woodchucks, this increase was associated with the nearly coincident
emergence of type II and/or type III mutants. Moreover, the type II
mutant appeared to be more efficient than the type I mutant at
displacing the wild type (and type I mutant) from the liver, despite
its much later appearance. One factor that may slow replacement of wild-type cccDNA is trans-complementation by mutant virus
polymerase. Evidence for this was provided by the observation that both
mutant and wild-type virus titers rose late in therapy (Table 2; Fig. 5).
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FIG. 5.
Time course of appearance of B-region mutants in
lamivudine-treated woodchucks (wc). The presence of different variants
was estimated by sequencing of PCR products, as described in Materials
and Methods. For woodchuck 4960, only wild-type (WT) virus was detected
at 8.5 months. In general, the results were confirmed by cloning and
sequence analysis of selected PCR products (Table 1).
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In addition to the mutations that arose during lamivudine treatment, we
detected a spontaneous mutation of the B region in one woodchuck
(woodchuck 4961) after 10 months of placebo treatment (Table 2). This
mutation, which changed the alanine at position 566 to a serine, was
previously observed in this animal but not in five other woodchucks
receiving placebo for the same length of time (17). This is
one of the three changes in the type III mutant. We therefore tested
this virus stock for lamivudine resistance in primary hepatocyte
cultures, following the procedure described in Fig. 2. This virus stock
responded to lamivudine like the wild-type virus described in Fig. 2A;
that is, there was no evidence that the mutation conferred lamivudine
resistance to the infectious virus in this serum sample. Insertion of
the mutation into wild-type viral DNA led to a slight increase in
resistance to lamivudine in transfected Huh7 cultures, characterized as
described above and shown in Fig. 3 (data not shown).
In an attempt to obtain additional information about the emergence of
mutant virus in the liver, we determined the genotypes of cccDNAs
isolated from biopsy specimens taken during the course of therapy
(17). cccDNA was purified, and the active-site region of the
polymerase was amplified by PCR. The genotypes of the PCR clones were
then determined, with the results shown in Table 2. With two of the
woodchucks (woodchucks 300 and 302), this analysis supported the
earlier conclusion, derived from the results of cell culture studies,
that the mutants were drug resistant in vivo and, therefore, replicated
more efficiently than the wild type in the presence of lamivudine. For
instance, after 5 months of treatment of woodchuck 300, all 30 clones
obtained after PCR amplification of cccDNA were wild type, whereas 14 of 36 clones derived from amplification of virion DNA had a type I
mutant genotype. Likewise, after 12 months, 11 of 29 cccDNA-derived
clones were wild type, whereas 34 of 34 clones derived from virus had a
B-region mutation.
For two of the four woodchucks (woodchucks 315 and 4960) whose results
are presented in Table 2 and Fig. 5, a replication advantage of mutant
virus was not evident simply by comparison of cccDNA and viral
genotypes. (For woodchuck 315, the very low virus titers after 12 months were probably due to a transient immunological reaction to the
infection rather than a direct simple consequence of the antiviral
therapy [17].) For these two woodchucks, as for
woodchucks 300 and 302, direct evidence that the mutants replicated
more efficiently than the wild type was provided by the observation
that mutant cccDNA supplanted the wild type as the prevalent species in
the liver during the course of therapy. The presence of elevated titers
of wild-type virus in the serum as total virus titers rise is
presumably a consequence of trans-complementation of the
wild-type pregenome by mutant WHV polymerase in a set of doubly
infected hepatocytes.
Taken together, the results suggest that the emergence of the type I
mutant and, by implication, of the type II and III mutants is impeded
by preexisting infection of hepatocytes with wild-type virus. Moreover,
this appears to be the case, despite the evidence from both cell
culture and in vivo studies that the mutants replicate more efficiently
than the wild type in the presence of lamivudine. Thus, a sustained
suppression of virus titers in the serum may reflect the stability of
wild-type cccDNA and of the hepatocytes that were infected by wild-type
virus rather than a significant loss of infection from the liver.
Consequences of mutations in the YMDD motif of WHV.
One
peculiar aspect of lamivudine-resistant WHV was the absence of
mutations of the YMDD motif, which characterize lamivudine-resistant variants of HBV and human immunodeficiency virus that emerge during therapy. Mutations were therefore inserted into wild-type WHV to change
the YMDD motif (Fig. 1) to either YIDD or YVDD. The mutant DNA was then
transfected into Huh7 cells in the presence and absence of lamivudine,
and the accumulation of intermediates in viral DNA synthesis was
assayed (Fig. 3). The YVDD mutant of WHV was drug resistant, although
it appeared to replicate poorly. Replication of the YIDD mutant was
essentially undetectable in this experiment, but replication and drug
resistance were demonstrated by more sensitive assays (data not shown).
Thus, the data suggest that one reason that the YVDD and YIDD variants
were not detected in vivo is that they may replicate inefficiently.
| |
DISCUSSION |
Our previous evaluation of lamivudine treatment of chronically
infected woodchucks reveals three unexpected problems (17). First, the decline in virus titers in the serum is very slow, extending
over several months. Second, the net suppression in virus titers is
less than 1,000-fold in most woodchucks. Third, virus titers invariably
rise again within 9 to 12 months.
The results presented above suggest that the overall decline in virus
titers is limited, at least in some woodchucks, by the presence of
drug-resistant WHV in the liver even early in therapy. This possibility
was consistent with the detection of the type I mutant in some
woodchucks as early as 5 months after the initiation of lamivudine
treatment. Assuming that the type I mutant replicated in the presence
of lamivudine with the same efficiency as wild-type WHV in the absence
of lamivudine, mutant cccDNA would be 0.2 to 1% of the total cccDNA at
this time. Indeed, analysis of the genotypes of cccDNA extracted from
woodchuck 300 at this time revealed only wild-type cccDNA (30 of 30 clones; Table 2).
Unfortunately, none of our experiments shows why virus titers do not
drop rapidly after initiation of lamivudine therapy, as they do in
HBV-infected patients. A prolonged WHV half-life in blood is not an
explanation. Rapid drops in WHV titer have been observed following even
short-term therapy with other nucleoside analogs. For example, one
group observed a 100-fold drop in WHV titers following initiation of
therapy with BMS-200475, indicating that the half-life of WHV in blood
is 1 day or even less (8). One possible explanation might be
that type I mutant cccDNA is distributed evenly through the hepatocyte
population. If this mutant cccDNA were a common variant in WHV
carriers, representing 1% of the total at the start of therapy, and
was spread evenly to hepatocytes containing an average of 20 cccDNA
molecules (wild type plus mutant cccDNA molecules), there would be
enough mutant cccDNA for 20% of the hepatocyte population. This could
help to explain why virus titers dropped only about 10-fold in the
first month even after treatment with very high doses of lamivudine (assuming efficient trans-complementation by the mutated polymerase).
This hypothesis for the slow decline in virus titers appears untenable,
however, as it fails to explain why titers keep dropping as therapy is
continued. If, instead, the type I variant is not initially spread
among hepatocytes but is the predominant or only cccDNA in those
hepatocytes in which it is initially present, a different picture
emerges. The slow decline in virus titers reflects some peculiarity in
uptake or phosphorylation of lamivudine in the woodchuck
(22).
An even more complex issue is the eventual enrichment of type I cccDNA
in the liver and the nearly complete replacement of wild-type cccDNA by
the type II variant. If both are initially present in only a few
hepatocytes, then the ultimate rise in virus titers and the enrichment
of their respective cccDNAs requires spread to hepatocyte lineages
originally infected with wild-type WHV. This requires that these
hepatocytes either lose the wild-type virus or becomes susceptible to
superinfection with the mutant virus. How this would occur is unknown.
One possibility is that inhibition of viral DNA synthesis, plus
elevated hepatocyte death and proliferation due to infection, leads to
dilution of wild-type DNA in hepatocyte lineages, making them
candidates for superinfection by the mutants. This type of mechanism
would help explain why in almost every woodchuck there is an identical
length of time between initiation of antiviral therapy and the eventual
rise in titers whether it is due to the spread of type I or type II variants. That is, the eventual takeover by mutant virus is entirely dependent upon the loss of wild-type WHV, which, in turn, is governed by the rate of death and proliferation of hepatocytes. The preferential takeover by type II and III variants, when detectable, may reflect the
fact that these two types have a higher replicative capacity than type
I, plus the fact that the continued presence of some wild-type WHV is
probably not required for their replication. (Because of the
introduction by the pol mutation of the type I variant of a
stop codon in the overlapping S gene [17], this virus
is presumably dependent on coinfection with wild-type virus to form
infectious virions; the effects of missense mutations in the S gene,
which are associated with the type II and III mutations, on the
formation of infectious virions are unknown.)
As noted earlier, a recent study on the appearance of
lamivudine-resistant strains of HBV, in which mutant virus was present in the serum of patients four months prior to an increase in virus titers, points to the same conclusions as our study (4):
that wild-type virus that remains in the liver may temporarily inhibit outgrowth of the drug-resistant variant. Whether or not this conclusion will be supported by further studies of clinical specimens remains to
be determined.
| |
ACKNOWLEDGMENTS |
We are grateful to G. Rall, C. Seeger, J. Summers (University of
New Mexico), B. Tennant (Cornell University), and J. Taylor for helpful
suggestions, to S. Berman for assistance in the preparation of the
manuscript, and to A. Cywinski and the DNA Sequencing Facility of the
Fox Chase Cancer Center for sequence determinations. Oligonucleotides were synthesized in the institutional DNA Synthesis Facility under the
direction of T. Yeung.
This work was supported by Public Health Service grants AI-18641,
3P01-CA-4073711S1, and CA-06927 from the National Institutes of Health
and by an appropriation from the Commonwealth of Pennsylvania.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Fox Chase Cancer
Center, 7701 Burholme Ave., Philadelphia, PA 19111. Phone: (215)
728-2402. Fax: (215) 728-3616. E-mail:
ws_mason{at}fccc.edu.
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Top
Abstract
Introduction
