Antiviral Activity of {beta}-L-2',3'-Dideoxy-2',3'-Didehydro-5-Fluorocytidine in Woodchucks Chronically Infected with Woodchuck Hepatitis Virus

doi:10.1128/AAC.45.4.1065-1077.2001

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Antimicrobial Agents and Chemotherapy, April 2001, p. 1065-1077, Vol. 45, No. 4
0066-4804/01/$04.00+0 DOI: 10.1128/AAC.45.4.1065-1077.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.

Antiviral Activity of $beta$ -L-2',3'-Dideoxy-2',3'-Didehydro-5-Fluorocytidine in Woodchucks Chronically Infected with Woodchuck Hepatitis Virus

F. Le Guerhier,¹ C. Pichoud,¹ C. Jamard,¹ S. Guerret,² M. Chevallier,³ S. Peyrol,⁴ O. Hantz,¹ I. King,⁵ C. Trépo,¹ Y.-C. Cheng,⁶ and F. Zoulim¹^,^*

INSERM Unit 271, 69003 Lyon,¹ Biomaterials Laboratory, Faculty of Pharmacy² and Electron Microscopy Center of Laennec University School of Medicine,⁴ 69008 Lyon, and Department of Pathology, Marcel Mérieux Laboratory, 69007 Lyon,³ France; VION Pharmaceuticals Inc., New Haven, Connecticut 06511⁵; and Department of Pharmacology, Yale University School of Medicine, New Haven, Connecticut 06520⁶

Received 18 May 2000/Returned for modification 28 August 2000/Accepted 10 January 2001

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

The L-nucleoside analog $beta$ -L-2',3'-dideoxy-2',3'-didehydro-5-fluorocytidine ( $beta$ -L-Fd4C) was first shown to exhibit potent activityagainst hepatitis B virus (HBV) in tissue culture and then tosignificantly inhibit viral spread during acute infection in theduck HBV model (F. Le Guerhier et al., Antimicrob. Agents Chemother.44:111-122, 2000). We have therefore examined its antiviral activityin a mammalian model of chronic HBV infection, the woodchuck chronicallyinfected with woodchuck hepatitis virus (WHV). Side-by-side comparisonof $beta$ -L-Fd4C and lamivudine administered intraperitoneally duringshort-term and long-term protocols demonstrated a more profoundinhibition of viremia in $beta$ -L-Fd4C-treated groups. Moreover, $beta$ -L-Fd4Cinduced a marked inhibition of intrahepatic viral DNA synthesiscompared with that induced by lamivudine. Nevertheless, covalentlyclosed circular (CCC) DNA persistence explained the lack of clearanceof infected hepatocytes expressing viral antigens and the relapseof WHV replication after drug withdrawal. Liver histology showeda decrease in the inflammatory activity of chronic hepatitis inwoodchucks receiving $beta$ -L-Fd4C. An electron microscopy study showedthe absence of ultrastructural changes of hepatic mitochondria,biliary canaliculi, and bile ducts. However, a loss of weightwas observed in all animals, whatever the treatment, as was atransient skin pigmentation in all woodchucks during $beta$ -L-Fd4Ctreatment. There was no evidence that lamivudine or $beta$ -L-Fd4C couldprevent the development of hepatocellular carcinoma with the protocolsused. These results indicate that $beta$ -L-Fd4C exhibits a more potentantiviral effect than lamivudine in the WHV model but was notable to eradicate CCC DNA and infected cells from the liver atthe dosage and with the protocolused.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Chronic hepatitis B virus (HBV) infection remains a major public health problem worldwide due to its natural history, whichincludes the progression to chronic hepatitis, liver cirrhosis,and hepatocellular carcinoma (25). The recent approval of lamivudine[ $beta$ -L( $-$ )-2',3'-dideoxy-3'-thiacytidine, also called 3TC or L( $-$ )SddC]has opened new perspectives for the therapy of chronic hepatitisB. In all clinical trials, 3TC was shown to be well toleratedand to be a very potent inhibitor of HBV replication (7, 24).However, due to the long half-life of infected hepatocytes andthe persistence of viral covalently closed circular (CCC) DNAin infected hepatocytes, long-term treatment is required to controlor eradicate viral infection (29, 34). The spontaneous HBVgenome variability gives rise to a progressive selection of drug-resistantvariants in 16 to 43% of the patients after 1 year of therapy(7, 24). These mutations located in the conserved B and Cdomains of the HBV reverse transcriptase confer resistance to3TC (2, 49).

Therefore, the design and evaluation of new molecules with anti-HBV activity remain major goals. With this aim, new antiviralcompounds are usually assessed in experimental models of hepadnavirusreplication (30), including in vitro hepatocyte culture (10,19, 31) and the convenient in vivo model of duck HBV (DHBV)infection (9, 27, 33, 47). The woodchuck model of HBVinfection (woodchuck hepatitis virus [WHV] infection) presentsmany features in common with the natural history of human HBVinfection, including the development of chronic hepatitis andhepatocellular carcinoma (40, 41). It is therefore a veryuseful model for the study of the antiviral activities of newcompounds as well as their pharmacokinetics (37) and safety(42). In this model, the potent inhibitory activities of newantivirals such as 3TC (18, 29), emtricitabine (FTC: ( $-$ )- $beta$ -L-2',3'-dideoxy-3'-thia-5-fluorocytosine)(6, 23), and entecavir (BMS-200475 or cyclopentyl guanosine)(12) was recently demonstrated. The inability to eradicate WHVCCC DNA, even with the most potent inhibitors of viral replication,was underlined, confirming the requirement of long-term antiviraladministration to control viral replication (12, 29). Theselection of 3TC-resistant variants harboring mutations in theB domain of the WHV reverse transcriptase was also demonstrated(44). The mitochondrial toxicity of fialuridine [1-(2-deoxy-2-fluoro- $beta$ -D-arabinofuranosyl)-5-iodouracil]was analyzed in detail in the woodchuck model, indicating itsrelevance for the evaluation of new antivirals (42).

Recently, the novel cytidine analog $beta$ -L-2',3'-dideoxy-2',3'-didehydro-5-fluorocytidine ( $beta$ -L-Fd4C) was synthesized, and itwas shown to inhibit HBV replication in the 2.2.1.5 cell linewithout inducing significant mitochondrial DNA toxicity in CEMcells (4, 28, 39, 45). Evaluation in the DHBV infectionmodel showed that $beta$ -L-Fd4C is a more potent inhibitor of the DHBVreverse transcriptase than 3TC and other cytidine analog triphosphatesand inhibits viral DNA synthesis in primary duck hepatocyte cultures.It was also demonstrated that early administration of $beta$ -L-Fd4Cafter experimental infection of ducklings dramatically inhibitsviral replication but does not prevent the progression to chronicinfection (26). To continue the evaluation of the anti-HBV activityof $beta$ -L-Fd4C, we have studied its inhibitory activity in woodchuckschronically infected with WHV in comparison with that of 3TC.The effects of these drugs on viremia, intrahepatic viral DNAsynthesis, clearance of infected cells, histologic activity ofchronic hepatitis, and development of hepatocellular carcinomawere analyzed. From the studies reported herein, we give evidencethat, in the woodchuck model, $beta$ -L-Fd4C is a potent inhibitor ofWHV replication invivo.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Drugs. $beta$ -L-Fd4C was synthesized in the Department of Pharmacology and the Comprehensive Cancer Center, Yale University School ofMedicine, New Haven, Conn., as described by Lin et al. (28).3TC was provided by VIONPharmaceuticals.

Treatment of woodchucks chronically infected with WHV. Twenty captive-born woodchucks (Marmota monax) (age, 12 months) experimentally infected with WHV were purchased from NortheasternWildlife (South Plymouth, N.Y.). The woodchucks were chronicallyinfected and were used for in vivo experiments. The treatmentprotocols were performed 3 months later, from July to December1998, in accordance with the guidelines for animal care at thefacilities of the National Veterinary School of Lyon (Marcy l'Etoile,France). $beta$ -L-Fd4C administration was performed by the intraperitonealroute to avoid its degradation at low pH, which may occur if itis given by the oral route. Six animals received $beta$ -L-Fd4C for15 weeks (group 1), four animals received in a first set of experiments $beta$ -L-Fd4C for 2 weeks and subsequently received $beta$ -L-Fd4C for 9weeks after a washout period of 8 weeks (group 2), four animalsreceived in a first set of experiments 3TC for 2 weeks and subsequentlyreceived 3TC for 9 weeks after a washout period of 8 weeks, andsix animals served as a control group. The two nucleoside analogswere administered intraperitoneally to woodchucks by the protocolsdescribed in the Results section, followed by a 4-month posttreatmentperiod. Blood samples were collected once a week for analysisof viral markers, drug tolerance, and progression of liver disease.Tolerance of antiviral administration was assessed by monitoringof animal weight and lactic acid levels (Lactate PAP; bioMérieux,Marcy l'Etoile, France) in the serum. Serum markers of liver diseasewere monitored, including gamma-glutamyltransferase levels (1)with the GGT kit (Boerhinger, Meylan, France) and alpha-fetoproteinlevels with the $alpha$ -FETO RIABEAD Diagnostic kit (Abbott, Rungis,France).

Liver biopsy. Surgical liver biopsies were performed after laparotomy under general anesthesia with 7.5 mg of tiletamin and 7.5 mg of zolazepam(Zoletil; Virbac, Carros, France) per kg of body weight priorto therapy and also during treatment in all woodchucks exceptanimal 607 because it was feeding its offspring. All the pretreatmentbiopsies were performed at the same time: 7 weeks before $beta$ -L-Fd4Ctreatment in group 1 and 2 weeks before the first course of $beta$ -L-Fd4Ctreatment (group 2) or 3TC treatment. All the on-treatment biopsieswere performed at the same time: 16 weeks after the first biopsy,which corresponded to 9 weeks of $beta$ -L-Fd4C treatment in group 1and to 3 weeks of the second course of $beta$ -L-Fd4C treatment in group2 and the group treated with 3TC. One-third of each sample wassnap frozen in liquid nitrogen and subsequently stored at $-$ 80°Cfor viral DNA analysis. Another part of the sample was fixed informalin and embedded in paraffin for liver histology and immunostaining.The last part of the sample was fixed in 1% osmium tetroxide forthe electron microscopy study. A macroscopic liver examinationwas also performed during biopsysessions.

Analysis of viremia. Viremia was assessed by quantitative detection of WHV DNA and WHV endogenous polymerase activity (EPA). WHV DNA from the serumof all woodchucks was detected by a specific dot blot hybridizationassay throughout the study. Fifty microliters of serum, previouslyclarified by centrifugation at 10,600 × g for 6 min at 4°C, wasspotted directly onto nitrocellulose filters (Sartorius, Göttingen,Germany) with the Hybri-Dot manifold apparatus (Life Technologies,Cergy Pontoise, France). After denaturation (0.2 M NaOH, 1 M NaCl),neutralization (0.5 M Tris-HCl [pH 8] with 1 M NaCl followed by2× SSC [1× SSC is 0.15 M NaCl plus 0.015 M sodium citrate]), andfixation (80°C for 2 h), the filters were hybridized with a full-lengthWHV genomic DNA probe labeled with $alpha$ -³²P (Ready to go; Amersham Pharmacia Biotech, Courtaboeuf, France)(47). The filters were scanned by PhosphoImager scanning software(Amersham Pharmacia Biotech), and spots were quantitated withImage Quant. The limit of detection of viral DNA in serum was500 pg/ml. WHV-associated DNA polymerase activity was assesseddirectly in 50-µl serum samples of all woodchucks throughout thestudy period. The level of specific phosphonoformic acid-inhibitable[³H]dTTP incorporation was calculated by measuring the differencein EPA obtained with and without phosphonoformic acid (16).The limit of detection of this assay was 1,000 cpm/ml.

WHV polymerase gene sequencing. WHV DNA was amplified by PCR with serum collected either at the end of the treatment period or at the last time point beforethe animals death, according to a protocol described previously(29), with minor modifications. With this aim, 100 µl of serumwas mixed with an equal volume of 10 mM Tris-HCl (pH 7.5)-10 mMEDTA-150 mM NaCl-0.1% sodium dodecyl sulfate and treated overnightwith 1 mg of proteinase K (Sigma, Saint-Quentin Fallavier, France)per ml at 45°C. After phenol-chloroform extraction and ethanolprecipitation, one-sixth of the DNA was amplified for 35 cycles(94°C for 1 min, 50°C for 1 min, and 72°C for 1 min) with Taqpolymerase (Perkin-Elmer, Courtaboeuf, France) and a specificprimer pair (5'-AGATTGGTTGGTGCACTTCT-3' [nucleotides 385 to 403]and 5'-AATTGTCAGTGCCCAACA-3' [nucleotides 1468 to 1451]), correspondingto the B and C domains of the reverse transcriptase gene, withreference to a previously published sequence (22). Another primerpair was used for a nested PCR with samples that were negativein the first round of amplification: 5'-GGATGTATCTGCGGCGTTT-3'(nucleotides 510 to 528) and 5'-CCCAAATCAAGAAAAACAGAACA-3' (nucleotides953 to 931). Sequencing reactions were performed by PCR amplificationin a final volume of 20 µl with 5 pmol of the second primer pair,100 ng of PCR products, and 8 µl of the BigDye Terminator premixaccording to the Applied Biosystems (Foster City, Calif.) protocolfor 25 cycles (94°C for 30 s, 55°C for 30 s, 60°C for 4 min).Removal of excess of BigDye Terminators was performed with exclusioncolumns, and the samples, which were dried in a vacuum centrifuge,were dissolved with 2 µl of deionized formamide containing 25mM EDTA (pH 8). Samples were loaded onto an Applied Biosystems373A sequencer and run for 12 h on a 4.5% denaturing acrylamidegel. The nucleotide sequence and the derived amino acid sequenceof the viral polymerase obtained from each sample were comparedto published sequences (22, 29).

WHV surface antigen quantitation. Due to the genome sequence homology and the cross-reactivity of WHV and HBV surface antigens with polyclonal antibodies (5,11), WHV surface antigen was detected in the serum of all woodchucksprior to therapy and at the time of the second liver biopsy withthe AUSRIA II-125 kit (Abbott) (48). The titer of WHV surfaceantigen was determined from the last positivedilution.

Analysis of intrahepatic viral DNA synthesis. Intrahepatic viral DNA was extracted from all liver biopsy specimens by a procedure described in detail elsewhere (20, 21).Liver biopsy samples were snap frozen in liquid nitrogen, storedat $-$ 80°C, and then analyzed for viral DNA. After homogenizationin 10 mM Tris-HCl (pH 7.5)-10 mM EDTA, the biopsy specimen wasdivided into two parts: one for isolation of total viral DNA (afterproteinase K digestion, phenol-chloroform extraction followedby ethanol precipitation) and the other for isolation of non-protein-bound,CCC viral DNA (after sodium dodecyl sulfate-KCl precipitationof protein-bound DNA, phenol-chloroform extraction of the supernatantfollowed by ethanol precipitation). In order to normalize thecellular DNA concentration in each sample, the DNA concentrationwas determined by UV densitometric analysis in comparison withthat for previously quantified DNA (High DNA Mass Ladder; LifeTechnologies) after electrophoresis through an agarose gel. Fourhundred nanograms of total DNA or the CCC DNA preparation wasthen subjected to electrophoresis through 1.5% agarose gels andtransferred by blotting to nylon membranes (Hybond N+; AmershamPharmacia Biotech). Viral DNAs were detected by hybridizationwith an $alpha$ -³²P-labeled probe representing the complete viral genome and quantitatedafter PhosphoImagerscanning.

Analysis of liver histology prior to and while on therapy. Three-micrometer-thick, formalin-fixed liver biopsy tissue sections were stained with hematoxylin-eosin-safran (HES) stainand examined under a light microscope. The degree of hepatocytenecrosis (acidophilic bodies), the level of inflammation of theportal tract and the intralobular space, and the fibrosis stagewere semiquantitatively assessed by using the Metavir score (3).Liver biopsy sections were also assessed for steatosis, ductularproliferation, hepatocyte dysplasia, and hepatocellularcarcinoma.

Immunostaining of liver sections for WHV surface antigen and WHV core antigen. Five-micrometer-thick deparaffinized liver tissue sections were incubated overnight with rabbit serum containing polyclonalantibody directed against the WHV surface antigen or the WHV coreantigen (1/2,000 dilution). This step was followed by incubationwith a biotinylated goat anti-rabbit immunoglobulin G (Dako, Trappes,France). The antigen-antibody complex was then revealed with streptavidin-horseradishperoxidase (Dako). The visualization was performed with the 3,3'-diaminobenzidinetetrahydrochloride chromogen substrate according to the manufacturer'sinstructions (Dako) (43). All specimens were evaluated blindwithout knowledge of the antiviralprotocol.

Examination by electron microscopy. Liver biopsy tissue was fixed in 1% osmium tetroxide in 150 mM sodium cacodylate HCl (pH 7.4), dehydrated in graded ethanol,and embedded in epoxy resin (Cipec, Paris, France). Seventy-five-nanometerultrathin sections were obtained on an LKB ultratome V (Leica,Nanterre, France), contrasted with methanolic uranyl acetate andlead citrate, and observed with transmission electron microscope1200EX (Jeol, Kyoto,Japan).

Examination of skin biopsy sections. Three-micrometer-thick formalin-fixed skin biopsy sections stained with HES stain and by the Fontana-Masson procedure wereexamined under a lightmicroscope.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Short-term $beta$ -L-Fd4C treatment of WHV-infected woodchucks induced a transient but more potent antiviral activity than 3TC. In preliminary dose-finding studies, intraperitoneal administration of $beta$ -L-Fd4C at a dosage of 1 mg/kg of body weight perday for 4 consecutive days induced a rapid and profound decreasein serum WHV DNA levels, followed by a rebound of viremia afterdrug cessation (data not shown). Then, a side-by-side comparisonof $beta$ -L-Fd4C and 3TC at 1 mg/kg/day for 15 consecutive days wasperformed with four woodchucks receiving 3TC, four animals treatedwith $beta$ -L-Fd4C, and six control animals receiving no treatment.Analysis of WHV DNA (Fig. 1A) and WHV EPA (Fig. 1B) in serum demonstratedthat $beta$ -L-Fd4C exhibited a significantly more potent antiviraleffect than 3TC at the same dose. In $beta$ -L-Fd4C-treated animals,WHV DNA levels decreased by 9.2-fold (range, $-$ 51.2- to $-$ 3.4-fold),while EPA decreased by 47.8-fold (range, $-$ 72.4- to $-$ 37.7 fold)and then returned to pretreatment values 1 week after drug withdrawal.The mean serum WHV DNA level and EPA remained stable or increasedin 3TC-treated animals and controls, respectively. No variationin body weight or lactic acid levels was observed (data not shown).

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FIG. 1. Short-term $beta$ -L-Fd4C administration induces a transient but more potent antiviral effect than 3TC. $beta$ -L-Fd4C and 3TC were administered intraperitoneally at 1 mg/kg/day for 15 consecutive days to four woodchucks (per group) chronically infected with WHV, and the results were compared with those for six control animals. Serum WHV DNA levels and WHV EPA were monitored throughout the therapy period and for 25 days after drug withdrawal and are plotted on a logarithmic scale. (A) Mean serum WHV DNA level in each group; (B) mean of WHV EPA. The black bar at the top of each panel indicates the antiviral treatment period. Standard deviations are indicated by error bars.

, controls;

, $beta$ -L-Fd4C; $bullet$ , 3TC.

Long-term $beta$ -L-Fd4C therapy induced a more pronounced inhibition of WHV replication than 3TC. Since the short-term protocol was not able to induce a sustained inhibition of viral replication, we examined whether a higherdose of $beta$ -L-Fd4C could allow spaced dosing for prolonged antiviraltherapy. Pilot studies with $beta$ -L-Fd4C at 4 mg/kg were performedfirst with a single injection of drug that induced a rapid dropin viremia levels which was maintained for 4 days (data not shown).Then, $beta$ -L-Fd4C was administered at 4 mg/kg/day for 3 consecutivedays (induction therapy) and was followed by twice-weekly administrationfor 2 weeks (maintenance therapy). This regimen with a spacingof the dose every 84 h allowed maintenance of the antiviral effectfor the 2 weeks of treatment (data not shown). As expected, arelapse of viremia was observed during the follow-upperiod.

According to these results, a long-term administration of $beta$ -L-Fd4C at 4 mg/kg for 15 weeks was initiated in six animals ( $beta$ -L-Fd4Cgroup 1). The drug was administered for 3 consecutive days asan induction therapy followed by a maintenance therapy (twiceweekly for 5 weeks). Results showed first a significant inhibitionof viremia (by 21.5-fold) to the limit of detection of the WHVEPA assay or close to the limit of detection of the WHV DNA assay(11.4-fold decrease; range, to 16.6- to $-$ 7.1-fold) in all animals,but then three of six woodchucks showed slight increases in viremialevels up to 1,878 pg/ml by the WHV DNA assay or 3,597 cpm/mlby the WHV EPA assay (Fig. 2). Since the evolution of weight andlactic acid levels were similar in treated animals and the animalsthe control group, the maintenance therapy was modified at week6 to 4 mg/kg thrice weekly for 9 more weeks. This allowed maintenanceof the antiviral effect until the end of the treatment (Fig. 2).

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FIG. 2. Suppression of viral replication during long-term $beta$ -L-Fd4C therapy is followed by a relapse of viremia. $beta$ -L-Fd4C and 3TC were administered intraperitoneally to woodchucks chronically infected with WHV. The long-term $beta$ -L-Fd4C protocol (group 1; six animals) started with an induction treatment at 4 mg/kg/day for 3 consecutive days, followed by a maintenance therapy at the same dosage twice a week, but this was modified at week 6 to a thrice-weekly administration for 9 more weeks. Moreover a side-by-side comparison of the antiviral activities of $beta$ -L-Fd4C and 3TC was performed with a schedule consisting of induction therapy for 5 consecutive days followed by maintenance therapy for 8 more weeks with thrice-weekly administration. $beta$ -L-Fd4C was administered at 4 mg/kg (group 2; four animals), and 3TC was administered at 10 mg/kg (four animals). The same control group consisting of six woodchucks was used. Viremia was monitored by assays for WHV DNA levels and WHV EPA, as indicated. The level of viremia for each animal and a mean curve for each group were plotted on the graphs (logarithmic scale). The white bars at the top of each panel indicate the antiviral treatment periods. Week 0 indicates the begining of the antiviral administration in $beta$ -L-Fd4C group 1.

These results were taken into account to design a second protocol in which $beta$ -L-Fd4C was administered at 4 mg/kg to four animals( $beta$ -L-Fd4C group 2) for 5 consecutive days as an induction therapyfollowed by a maintenance therapy thrice weekly for 8 more weeks.The results were compared with those obtained with 3TC, whichwas administered at a dose of 10 mg/kg by the same schedule usedfor $beta$ -L-Fd4C group 2. In the control group, spontaneous fluctuationsof viremia levels were observed throughout the study period (Fig.2). During the 3TC treatment period, both assays showed a firstphase of viremia drop followed by successive phases of a riseand a drop of viremia. In contrast, in $beta$ -L-Fd4C group 2 a rapidand significant decrease in the level of viremia to the levelof detection of the WHV EPA assay (38.7-fold decrease) or closeto the limit of detection of the WHV DNA assay (31-fold decrease)was observed and maintained until the end of thetherapy.

At the end of therapy or at the last time point before animal death, polymerase gene sequence analysis was performed withvirus from all 20 woodchucks. The results showed the presenceof wild-type WHV polymerase sequences, indicating the absenceof selection of WHV mutants in the B and C domains of the reversetranscriptase gene (data not shown). After drug withdrawal, viremialevels in all groups of treated animals returned to pretherapyvalues in 4 to 6 weeks for the $beta$ -L-Fd4C groups and in 10 weeksfor the 3TC group (Fig. 2).

Long-term $beta$ -L-Fd4C therapy strongly inhibited WHV DNA replicative intermediate synthesis but was not sufficient to clear intrahepatic CCC DNA. Liver biopsies were performed prior to therapy and after 9 weeks of therapy in $beta$ -L-Fd4C group 1 and after 3 weeks of treatmentin $beta$ -L-Fd4C group 2 or the 3TC group. Southern blot analysis ofthe intrahepatic viral DNA prior to treatment showed the naturalvariation of WHV replication from animal to animal in all groups(Fig. 3A). A marked decrease in the level of viral DNA synthesiswas observed in both $beta$ -L-Fd4C groups, with 5- to 30-fold decreasesin the levels of intrahepatic viral DNA intermediates comparedto the pretreatment levels (Fig. 3B). In contrast, in the 3TCgroup, no significant variation in intrahepatic viral replicationwas observed (range, $-$ 3.8- to +2.3-fold variation), which wascomparable to that for the control group (range, $-$ 3- to +2.2-foldvariation). However, the inhibition of WHV replication by $beta$ -L-Fd4Cadministration was not followed by the clearance of intrahepaticviral CCC DNA, as demonstrated by Southern blot analysis (Fig.3B). Moreover, this viral DNA form persisted whatever the durationof $beta$ -L-Fd4C treatment.

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FIG. 3. $beta$ -L-Fd4C treatment inhibits WHV DNA synthesis in the liver but is not sufficient to clear CCC DNA. Total DNA and CCC DNA were extracted from liver biopsy specimens obtained prior to therapy and while on therapy as described in the Materials and Methods section and were then analyzed by Southern blotting followed by specific hybridization. (A) Results prior to the beginning of therapy. (B) Results at week 9 of therapy in $beta$ -L-Fd4C group 1 and after 3 weeks of therapy in $beta$ -L-Fd4C group 2 or the 3TC group. Data for animal 607 were not included in this analysis, as explained in the Materials and Methods section. The sizes of the molecular weight markers are indicated on the left of each panel.

As viral CCC DNA represents the template for viral gene expression, we analyzed the titers of serum WHV surface antigen priorto and while on therapy, at the time of the liver biopsies. Theserum WHV surface antigen titer remained stable (10⁴) in the control group. A slight decrease in the surface antigenWHV titer from 1 × 10⁴ to 1 × 10³ was observed in three animals in $beta$ -L-Fd4C group 1, while oneanimal had an increase in titer from 1 × 10⁴ to 5 × 10⁴ in $beta$ -L-Fd4C group 2 and the titers in the other six $beta$ -L-Fd4C-treatedwoodchucks remained stable. Among the animals in the 3TC group,one woodchuck had a decrease in the WHV surface antigen titer(from 5 × 10⁴ to 1 × 10⁴), while the titers in the other three animals were stable. Overalland consistent with the results obtained by CCC DNA detection,there were no significant changes in the WHV surface antigen titersin the sera of 3TC- and $beta$ -L-Fd4C-treatedanimals.

Absence of clearance of WHV-infected hepatocytes during long-term therapy with $beta$ -L-Fd4C. The rate of infected hepatocytes during $beta$ -L-Fd4C or 3TC therapy was analyzed by immunostaining with specific antibodies directedagainst WHV surface or core antigens. Infected hepatocytes expressingviral antigens were observed in the parenchyma and were preferentiallyclustered in perivascular regions of the hepatic lobule (Fig.4). The anti-core antigen antibody staining was cytoplasmic andperinuclear (Fig. 4), while the WHV anti-surface antigen antibodystaining was mainly cytoplasmic (data not shown). In some animals,the macrovesicular steatosis pushed the cytoplasmic staining tothe cellular membrane. Viral envelope and core antigen expressionwas also noted in some inflammatory cells of the portal tracts,i.e., Kupffer cells, but biliary cells were not stained by anti-WHVantibodies. Whatever the antiviral protocol performed, the numberof infected hepatocytes and the level of viral protein expressionwere not significantly modified in the control group or treatedanimals (Fig. 4).

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FIG. 4. $beta$ -L-Fd4C and 3TC treatments do not decrease significantly the number of infected hepatocytes. The immunostaining studies presented were performed with liver biopsy sections obtained prior to therapy and while on therapy with specific polyclonal anti-WHV core antibodies as described in Materials and Methods. Representative results obtained for each group of animals are depicted. (1a) Liver section of animal 613 (control group) prior to therapy. (1b) Liver section of animal 613 (control group) while on therapy. (2a) Liver section of animal 623 ( $beta$ -L-Fd4C group 1) prior to therapy. (2b) Liver section of animal 623 ( $beta$ -L-Fd4C group 1) while on-therapy, (3a) Liver section of animal 621 ( $beta$ -L-Fd4C group 2) prior to therapy. (3b) Liver section of animal 621 ( $beta$ -L-Fd4C group 2) while on therapy. (4a) Liver section of animal 620 (3TC group) prior to therapy. (4b) Liver section of animal 620 (3TC group) while on therapy. Bar, 100 µm.

Decrease in chronic hepatitis activity in $beta$ -L-Fd4C-treated animals. Analysis of liver histology was performed with the biopsy specimens obtained prior to and while on therapy (Fig. 5). The Metavirscore was used to assess the evolution of the hepatitis activityand liver fibrosis (Table 1). Results showed a decrease in theinflammatory activity of chronic hepatitis and a stability ofliver fibrosis in woodchucks treated with $beta$ -L-Fd4C for 9 weeks(Fig. 5A and B), while in control animals, hepatitis activityincreased and the level of liver fibrosis tended to decrease.After 3 weeks of therapy, the four animals in $beta$ -L-Fd4C group 2showed stable liver histology, while the four woodchucks in the3TC group showed a stable hepatitis activity and a slight increasein the levels of liver fibrosis.

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FIG. 5. Decrease of hepatitis activity by 9 weeks of $beta$ -L-Fd4C therapy but development of hepatocellular carcinoma in all groups of woodchucks. Analysis of liver histology was performed with biopsy specimens obtained prior to and while on therapy. (A) Liver section of animal 625 ( $beta$ -L-Fd4C group 1) prior to therapy (magnification ×570). (B) Liver section of animal 625 ( $beta$ -L-Fd4C group 1) while on therapy (magnification, ×570). Note the decrease in the level of the inflammatory infiltrates and the stable liver fibrosis during treatment. (C) Liver section of animal 625 ( $beta$ -L-Fd4C group 1) while on therapy (magnification, ×228). Note the progression of the liver disease with the presence of a dysplasic nodule (with marked hepatocyte dysplasia). (D) Liver section of animal 623 ( $beta$ -L-Fd4C group 1) while on therapy (magnification, ×570). Note the progression of the liver disease with the development of hepatocellular carcinoma.

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TABLE 1. Analysis of liver histology after surgical biopsy of woodchucks, prior to therapy, and after 3 weeks of treatment with $beta$ -L-Fd4C (group 2) or 3TC and 9 weeks of therapy in $beta$ -L-Fd4C (group 1)^a

Although $beta$ -L-Fd4C and 3TC administration inhibited viral replication to different extents and acted on liver disease, sixanimals died of hepatocellular carcinoma during the study period(4 of 10 in the $beta$ -L-Fd4C groups, 1 of 4 in the 3TC group, and1 of 6 in the control group), 3 other animals died during thesecond biopsy session but already presented with hepatocellularcarcinoma, and one animal died with a liver with signs of necrosis(Table 1). All the remaining animals died naturally or were euthanatizedduring the 10-month period following the end of the study andpresented with hepatocellular carcinoma (9 of 10 animals) or markedliver dysplasia (1 of 10 animals). Diagnosis of hepatocellularcarcinoma was made by both macroscopic and microscopic examinationof the liver. Interestingly, liver histology analysis showed inmost animals the sequential occurrence of dysplasic nodules andprogression to hepatocellular carcinoma during antiviral treatment(Fig. 5C and D). Follow-up of alpha-fetoprotein levels did notreveal significant variations over time and was not associatedwith the evolution toward hepatocellular carcinoma (data notshown).

Analysis of animal tolerance to antiviral therapy. Lactic acid levels and animal weight were assessed throughout the study. A loss of weight was observed in the animals in the $beta$ -L-Fd4C groups (from 4 ± 0.6 to 2.5 ± 0.3 kg) as well as in thosein the 3TC group (from 4.3 ± 0.8 to 3.2 ± 0.1 kg) and in the controlgroup (from 3.7 ± 0.7 to 2.9 ± 0.4 kg), although lactic acid levelswere normal for all animals (data not shown). Gamma-glutamyltransferasequantitation revealed at the time of the second liver biopsy thepresence of elevated gamma-glutamyltransferase levels in nineanimals distributed among all groups tested (Table 1). However,although the gamma-glutamyltransferase level elevation was specificallyassociated with the occurrence of hepatocellular carcinoma (observedin eight animals), the association was not sensitive enough sincein five animals in which hepatocellular carcinoma was observedmacroscopically gamma-glutamyltransferase levels were within thenormal range. Study of liver sections from all treated animalsafter 3 or 9 weeks of therapy by electron microscopy showed theabsence of ultrastructural modification of hepatocyte mitochondria(Fig. 6A), biliary canaliculi (Fig. 6B), and bile duct epithelialcells (Fig. 6C) in $beta$ -L-Fd4C- and 3TC-treated animals as well asin the control group (Fig. 6D). Surprisingly, homogeneous skinhyperpigmentation slowly appeared in all $beta$ -L-Fd4C-treated animals,after 4 weeks of treatment in group 2 and 10 weeks of treatmentin group 1, corresponding to the switch from biweekly to thrice-weeklyadministration. Skin histology performed at the end of therapyand 8 weeks after drug cessation revealed an accumulation of melaninpigment throughout the entire epidermal layer that was progressivelyeliminated to the upper level of the epidermis by natural cellturnover after drug withdrawal (Fig. 7).

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FIG. 6. Absence of cytotoxicity-related ultrastructural change of hepatocyte mitochondria, biliary canaliculi, and bile ducts during therapy. The ultrastructure of the mitochondria, biliary canaliculi, and bile ducts were analyzed by electron microscopy of liver biopsy specimens after 3 or 9 weeks of therapy, as described in Materials and Methods. (A) Hepatic trabecula of animal 623 ( $beta$ -L-Fd4C group 1). Mitochondria showed a normal aspect, with tight intermembrane spaces and regularly distributed cristae into the homogeneously electron-dense matrix. (B) Hepatocytic biliary poles of animal 620 (3TC group). The bile canaliculi were regularly distributed between hepatocytes, with well-preserved limiting-membrane junctional complexes and well-developed intracanalicular hepatocytic microvilli. A physiological amount of lipopigments was deposited in the pericanalicular hepatocytic cytoplasm. Note the normal mitochondrial population. (C) Bile ductule of animal 620 (3TC group). Note the normal aspect of the periductal basal lamina, the polarized distribution of epithelial cell organelles, interepithelial cell contact, and ductal lumen with epithelial cell microvilli. (D) Hepatocytic trabecula with sinusoid of animal 609 (control group). Major steatosis was observed, with micro- and macrovesicular accumulations of triglycerides. The sinusoidal vessel was congested with hepatocytic cytoplasmic fragments and inflammatory cells (neutrophil polymorphonuclear cell, hypertrophic Kupffer cell). A stellate cell was present in the Disse space. Note the normal aspect of mitochondrias. m, mitochondria; n, nucleus; sv, steatosis vesicle; j, membrane junctional complexes; mv, microvilli; lp, lipopigment; bl, basal lamina; Kc, Kupffer cell; Sc, stellate cell; Npc, neutrophilic polymorphonuclear cell. Bars, 2 µm.

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FIG. 7. Transient skin pigmentation during $beta$ -L-Fd4C therapy of WHV-infected woodchucks. Skin biopsies were performed at the end of $beta$ -L-Fd4C therapy and 8 weeks after drug withdrawal. (1a) Skin section of animal 613 (control group) analyzed by staining with HES stain at the end of therapy. (1b) Skin section of animal 613 (control group) stained with Fontana-Masson stain at the end of therapy. Note the normal epidermis and upper dermis in the control with the absence of melanin pigment on Fontana-Masson staining. (2a) Skin section of animal 623 ( $beta$ -L-Fd4C group 1) analyzed by staining with HES stain at the end of therapy. (2b) Skin section of animal 623 ( $beta$ -L-Fd4C group 1) stained with Fontana-Masson stain at the end of therapy. Note the overload of all the epidermal layers including the stratum corneum by melanic pigmentation, as visualized by Fontana-Masson staining. (3a) Skin section of animal 623 ( $beta$ -L-Fd4C group 1) analyzed by staining with HES stain posttherapy. (3b) Skin section of animal 623 ( $beta$ -L-Fd4C group 1) stained with Fontana-Masson stain posttherapy. Note the transient effect of $beta$ -L-Fd4C on the skin pigmentation after drug cessation. The hyperpigmentation is retained in the upper part of the epidermis (horny layer [arrow]), while the basal layer and spinosum stratum are free of pigment. Magnifications, ×225.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

In the work described here the antiviral activity of $beta$ -L-Fd4C was analyzed in vivo in the mammalian model of WHV infectionand was compared with that of 3TC, another L-deoxycytidine analog.Both short-term and long-term treatments with $beta$ -L-Fd4C at a doseof 1 or 4 mg/kg administered intraperitoneally allowed inhibitionof WHV replication. However, this was followed by a relapse ofviral replication after drug withdrawal, as already describedin this model with other nucleoside analogs (6, 12, 18,42), but with a longer delay for the case of the 3TC group inour experiment. The inhibition of viremia assessed by WHV DNAdetection and determination of EPA was, however, less pronouncedthan that observed with a recently developed compound, cyclopentylguanosine (entecavir; BMS-200475), which allowed 10⁷- to 10⁸-fold decreases in viremia titers (12). By comparison, 3TC wasonly moderately active against WHV replication, as already observedwith a dosage of 5 mg/kg administered orally (12). In a recentlypublished study, 3TC had to be administered at an oral dose of200 mg/kg to obtain a significant antiviral effect in woodchucks(29). These results are consistent with the more potent inhibitoryeffect of $beta$ -L-Fd4C on the DHBV reverse transcriptase in vitroand in vivo in comparison with that of 3TC in the duck model ofHBV infection (26). Therefore, it would be interesting to gaincomparative information on the in vivo metabolisms of 3TC and $beta$ -L-Fd4C in both the duck and woodchuck models by comparison withthose inhumans.

Prolonged $beta$ -L-Fd4C treatment for 15 weeks was not able to achieve clearance of intrahepatic viral CCC DNA, explaining therelapse of viral replication after the cessation of therapy. Thisis consistent with the results obtained with the duck model ofHBV infection with antiviral therapy based on 2'-carbodeoxyguanosineor FTC (9), as well as in the woodchuck model with 3TC (29),FTC (6), and cyclopentyl guanosine (12). This was associatedwith the absence of a decline in the number of infected hepatocytesand the WHV surface antigen titer in serum, suggesting that theresidual viral CCC DNA is an active template for viral genomeexpression, allowing the reinitiation of viral replication whentherapy is stopped. Genome sequence analysis of the B and C domainsof the polymerase gene of the dominant virus in the sera of theanimals demonstrated the wild-type sequence, suggesting the absenceof selection of drug-resistant mutants in $beta$ -L-Fd4C- or 3TC-treatedanimals with this duration of treatment. However, selection ofdrug-resistant mutants has previously been observed after longerdurations (>9 to 12 months) of 3TC treatment in the woodchuckmodel (44). As the rise in the viremia titer associated withthe selection of drug-resistant mutants was shown to depend onthe clearance of hepatocytes infected with wild-type virus (44),in our experiments we cannot rule out that this process was ongoingwhen therapy was stopped. As direct sequencing of the PCR productmay allow detection of minor variants representing 10 to 20% ofthe circulating viral quasispecies, clonal analysis may alreadyhave revealed the presence of mutants as minorspecies.

It was recently shown in the woodchuck model of hepadnavirus infection that the recruitment of CD4⁺ and CD8⁺ T cells and the production of gamma interferon and tumor necrosisfactor alpha in the infected liver, accompanied by a significantincrease in apoptosis and regeneration of heptocytes, are criticalevents involved in viral clearance (15). In light of these observations,the evaluation of combination treatment strategies based on theuse of reverse transcriptase inhibitors and immune modulatorssuch as the DNA vaccine approach (38, 46) to enhance the clearanceof infected cells iswarranted.

Interestingly, we observed a decrease in liver histology activity in $beta$ -L-Fd4C-treated animals. Since the number of animalswas limited in this study, further investigations are warrantedto determine whether prolonged antiviral treatment may controlthe progression of the liver disease, as suggested in clinicaltrials with 3TC (7, 24). Since expression of WHV antigenin the liver induces an antiviral immune response that leads tochronic disease, the decrease of hepatitis activity during $beta$ -L-Fd4Ctherapy could also be explained by an immunomodulatory actionof this antiviral since the number of infected cells and the levelof viral protein expression were apparently not significantlymodified by our protocol. However, in our woodchuck cohort, whichwas obtained at 12 months of age and treated 4 months later inthe long-term $beta$ -L-Fd4C group 1 protocol, this beneficial effecton liver histology was not sufficient to prevent or delay theoccurrence of liver cell dysplasia and subsequently the developmentof hepatocellular carcinoma. Accordingly, in another study, long-term3TC therapy of chronically infected woodchucks did not preventthe occurrence of hepatocellular carcinoma (29). WHV-inducedliver cancer involves a cascade of complex events including earlyviral genome integration in the N-myc and c-myc proto-oncogenesas well as hepatocyte turnover (8, 32). As the rate of hepatocellularcarcinoma reaches 25% of the infected animals each year (13,36), our findings suggest that early antiviral interventionshould be evaluated as prophylaxis for hepatocellularcarcinoma.

Indeed, a study performed with younger animals showed that long-term 3TC treatment may delay the development of hepatocellularcarcinoma in this model (S. F. Peek, I. A. Toshkov, H. N. Erb,R. F. Shinazi, B. E. Korba, P. J. Cote, J. L. Gerin, and B. C.Tennant, Abstr. Am. Assoc. Study Liver Dis., abstr. 957,1997).

As fialuridine was responsible for major mitochondrial toxicity in humans as confirmed with the woodchuck model (42), thepotential toxicity of $beta$ -L-Fd4C was another very important issuethat was addressed with the woodchuck model. Whether the lossof weight that was observed during $beta$ -L-Fd4C therapy could be relatedto the occurrence of hepatocellular carcinoma, the physiologyof the woodchuck during hibernation, or side effects of $beta$ -L-Fd4Cneeds to be determined by further toxicological studies. Indeed,careful electron microscopy analysis of liver samples during antiviraltreatment did not reveal any significant ultrastructural modificationsto hepatocyte mitochondria, biliary canaliculi, or bile ductsin $beta$ -L-Fd4C- and 3TC-treated animals, suggesting an absence ofliver cytotoxicity of these antivirals under our experimentalconditions, as already observed with 3TC treatment in humans (17).However, skin hyperpigmentation related to an accumulation ofmelanin pigment was observed during $beta$ -L-Fd4C treatment and slowlydisappeared after drug withdrawal. This skin modification maybe related to the particular physiology of the woodchuck, especiallysince therapy was performed in part during the hibernation period,when the general metabolism of these animals is greatly modified.A similar hyperpigmentation phenomenon has been described in patientstreated with zidovudine and was reproduced in mice experimentallyreceiving zidovudine (14, 35). The molecular mechanisms responsiblefor this increase in melanocyte activity as a result of nucleosideanalog administration and their relation to hibernation remainto beelucidated.

In conclusion, the results of our study suggest that although $beta$ -L-Fd4C exhibits a more potent antiviral effect than 3TC ina mammalian model of HBV infection, clearance of viral CCC DNAand infected cells from the liver is difficult to achieve withmonotherapy with a potent inhibitor of viral replication. Furthermore,effective prevention of hepatocellular carcinoma in this animalmodel may require an early therapeutic intervention, before theintegration of viral genome sequences in the host genome. Futureapproaches that combine antivirals and immune modulators for theeradication of chronic hepadnavirus infection should beevaluated.

	ACKNOWLEDGMENTS

This work was supported by grants from INSERM, the French Association for Research against Cancer, and the French League againstCancer and grants AI38204 and CA63477. F. Le Guerhier was therecipient of a fellowship from the French League againstCancer.

	FOOTNOTES

^* Corresponding author. Mailing address: INSERM Unit 271, 151 cours Albert Thomas, 69003 Lyon, France. Phone: (33) 4 72 68 1970. Fax: (33) 4 72 68 19 71. E-mail: zoulim{at}lyon151.inserm.fr.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

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1.	Abe, K., T. Kurata, T. Shikata, and B. C. Tennant. 1988. Enzyme-altered liver cell foci in woodchucks infected with woodchuck hepatitis virus. Jpn. J. Cancer Res. 79:466-472[CrossRef][Medline].
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Antiviral Activity of -L-2',3'-Dideoxy-2',3'-Didehydro-5-Fluorocytidine in Woodchucks Chronically Infected with Woodchuck Hepatitis Virus

Antiviral Activity of $beta$ -L-2',3'-Dideoxy-2',3'-Didehydro-5-Fluorocytidine in Woodchucks Chronically Infected with Woodchuck Hepatitis Virus