Interferon-Regulated Pathways That Control Hepatitis B Virus Replication in Transgenic Mice

We previously showed that the intrahepatic induction of cytokinessuch as alpha/beta interferon (IFN- ${alpha}$ /ß) and gamma interferon(IFN- ${gamma}$ ) inhibits hepatitis B virus (HBV) replication noncytopathicallyin the livers of transgenic mice. The intracellular pathway(s)responsible for this effect is still poorly understood. To identifyinterferon (IFN)-inducible intracellular genes that could playa role in our system, we crossed HBV transgenic mice with micedeficient in IFN regulatory factor 1 (IRF-1), the double-strandedRNA-activated protein kinase (PKR), or RNase L (RNase L) (IRF-1^-/-,PKR^-/-, or RNase L^-/- mice, respectively), three well-characterizedIFN-inducible genes that mediate antiviral activity. We showedthat unmanipulated IRF-1^-/- or PKR^-/- transgenic mice replicateHBV in the liver at slightly higher levels than the respectivecontrols, suggesting that both IRF-1 and PKR individually appearto mediate signals that modulate HBV replication under basalconditions. These same animals were responsive to the antiviraleffects of the IFN- ${alpha}$ /ß inducer poly(I-C) or recombinantmurine IFN- ${gamma}$ , suggesting that under these conditions, eitherthe IRF-1 or the PKR genes can mediate the antiviral activityof the IFNs or other IFN-inducible genes mediate the antiviraleffects. Finally, RNase L^-/- transgenic mice were undistinguishablefrom controls under basal conditions and after poly(I-C) orIFN- ${gamma}$ administration, suggesting that RNase L does not modulateHBV replication in this model.

INTRODUCTION

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Introduction

Hepatitis B virus (HBV) is a noncytopathic, enveloped virusthat causes acute and chronic hepatitis and hepatocellular carcinoma(4). It was previously shown that the intrahepatic inductionof alpha/beta interferon (IFN- ${alpha}$ /ß) that occurs in thelivers of HBV transgenic mice after injection of poly(I-C) orinfection with unrelated hepatotropic viruses, such as lymphocyticchoriomeningitis virus and adenovirus (9, 21), downregulatesHBV replication noncytopathically (21). The contribution ofIFN- ${alpha}$ /ß to this process was demonstrated by showingthat antiviral activity is completely blocked in HBV transgenicmice that were either genetically deficient for the IFN- ${alpha}$ /ßreceptor (21) or treated with antibodies to IFN- ${alpha}$ /ß(10). Recent studies have shown that the mechanism whereby IFN- ${alpha}$ /ßinhibits HBV replication in the transgenic mouse liver relieson the inhibition of formation and/or the destabilization ofimmature HBV RNA-containing capsids (29).

The intrahepatic induction of gamma interferon (IFN- ${gamma}$ ) also inhibitsHBV replication noncytopathically; this effect is achieved byinjecting HBV transgenic mice with HBV-specific cytotoxic Tlymphocytes (10, 21) or interleukin 12 (3) or by infecting themwith mouse cytomegalovirus (2). Experiments with antibodiesto IFN- ${gamma}$ or mice genetically deficient for IFN- ${gamma}$ have demonstratedthe importance of this cytokine as a mediator for the antiviralactivity of these stimuli.

Upon binding to specific surface receptors, IFN- ${alpha}$ /ßand IFN- ${gamma}$ activate a variety of IFN-inducible genes, some ofwhich trigger common intracellular antiviral pathways (25).A large variety of IFN-inducible genes have been identifiedto date; most of these are activated by the JAK-STAT signaltransduction cascade (6, 7, 14, 25, 34). However, how thesegenes exert their intracellular antiviral activities is stillpoorly understood. Among the interferon (IFN)-inducible genes,those for the IFN regulatory factor 1 (IRF-1), RNase L, anddouble-stranded RNA-activated protein kinase (PKR) systems aresome of the best characterized. IRF-1 is an IFN-inducible transcriptionfactor that regulates nitric oxide production (1, 19) and cytokinesignaling (22) and mediates antiviral activities against severalviruses, including coxsackievirus (19). RNase L, a cellularRNase activated by 2',5'-oligoadenylates produced by IFN-induced,double-stranded RNA-dependent synthetase (2',5'-OAS), degradesviral and cellular RNAs (5, 15, 31). This pathway has been shownto selectively reduce the intracellular RNA content of virusessuch as human immunodeficiency virus (20), encephalomyocardarditisvirus (EMCV) (18), and vaccinia virus (8). The inhibition ofviral protein synthesis initiation by IFN-inducible PKR hasbeen shown to suppress certain viral infections, including thosewith EMCV (14) and reovirus (23). Recently, the interactionbetween the hepatitis C virus NS5 and E2 proteins and PKR wassuggested to reduce the sensitivity of this virus to IFN- ${alpha}$ /ß(13, 26, 28).

Based on the aforementioned studies, it is possible that theIRF-1, RNase L, or PKR genes represent intracellular candidategenes that mediate the antiviral activities of IFN- ${alpha}$ /ßand/or IFN- ${gamma}$ in our system. To test this hypothesis, we crossedtransgenic mice that replicate HBV with mice that are geneticallydeficient for IRF-1, RNase L, or PKR (IRF-1^-/-, RNase L^-/-,or PKR^-/- mice, respectively), and we monitored the contributionsof these gene products to the antiviral effects of the systemicadministration of poly(I-C) or IFN- ${gamma}$ .

MATERIALS AND METHODS

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Materials and Methods

Mice. The HBV transgenic mouse lineage 1.3.32 (inbred C57BL/6) usedin this study (official designation, Tg[HBV 1.3 genome]Chi32)was described previously (11). These mice replicate HBV at highlevels in the liver without any evidence of cytopathology. Lineage1.3.32 was crossed with IRF-1^-/- (16, 27), RNase L^-/- (32),or PKR^-/- (30) mice. IRF-1^-/- mice were obtained from JacksonLaboratory (Bar Harbor, Maine). Heterozygous mice from lineage1.3.32 were repeatedly backcrossed with homozygous mice fromeach of the three knockout lineages to yield progeny that werescreened for hepatitis B e antigen (HBeAg) in the serum (byusing a commercially available kit from Abbott Laboratories,Abbott Park, Ill.). HBeAg-positive progeny were screened forhomozygosity of the null mutations by PCR as described previously(16, 30, 32). Mice found either homozygous or heterozygous forthe null mutation were matched for age (8 to 10 weeks), sex(male), and levels of HBeAg in their serum before experimentalmanipulations. All animals were housed in pathogen-free roomsunder strict barrier conditions.

Poly(I-C) and IFN- ${gamma}$ treatments. Mice were injected intravenously with a single dose of eitherpoly(I-C) complex (Sigma Chemical Co., St. Louis, Mo.) (200µg/mouse) or recombinant murine IFN- ${gamma}$ (Genentech, Inc.,San Francisco, Calif.) (200,000 U/mouse) and sacrificed 24 hlater. Their livers were processed for histological analysisor snap frozen in liquid nitrogen and stored at -80°C forsubsequent molecular analyses (see below).

Tissue DNA and RNA analyses. Frozen liver tissue was mechanically pulverized under liquidnitrogen, and total genomic DNA and RNA were isolated exactlyas previously described (11). Analyses of HBV DNA by Southernblotting and various cytokine and 2',5'-OAS mRNAs by an RNaseprotection assay (RPA) were performed exactly as previouslydescribed (10, 11). The relative abundances of specific DNAand RNA molecules were quantitated by phosphorimaging analysiswith Optiquant image analysis software (Packard, Meriden, Conn.).

Biochemical and histological analyses. The extent of hepatocellular injury was monitored by measuringserum alanine aminotransferase (sALT) activity at multiple timepoints after treatment with saline, poly(I-C), or IFN- ${gamma}$ . sALTactivity was measured with a Paramax chemical analyzer (BaxterDiagnostics Inc., McGaw Park, Ill.) exactly as previously described(10). For histological analysis, liver tissue samples were fixedin 10% zinc-buffered formalin (Anatech, Battle Creek, Mich.),embedded in paraffin, sectioned (3 µm), and stained withhematoxylin and eosin exactly as described elsewhere (10).

Statistical analysis. A two-tailed nonparametric Wilcoxon test was used to assessthe statistical significance of the experimental variation inthe intrahepatic content of HBV replicative forms among transgenicmice that were either heterozygous or homozygous for the IRF-1or PKR null mutation. A P value of <0.05 was considered significant.

RESULTS AND DISCUSSION

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Results and Discussion

Higher levels of HBV replication in the livers of IRF-1^-/- or PKR^-/- mice. HBV transgenic mice from lineage 1.3.32 were crossed with IRF-1^-/-,RNase L^-/-, or PKR^-/- mice. Groups (six mice per group) of age(8 to 10 weeks)-, sex (male)-, and serum HBeAg-matched animalsthat were either heterozygous (plus/minus) or homozygous (minus/minus)for the respective null mutation were sacrificed, and theirlivers were harvested. Following extraction, total hepatic DNAswere pooled for each group and analyzed for HBV replicationby Southern blot analysis.

As shown in Fig. 1, IRF-1^-/- or PKR^-/- mice replicated HBV inthe liver at levels about 2.2- or 1.5-fold higher than the respectiveheterozygous control littermates or RNase L^-/- mice (as measuredby phosphorimaging analysis with the transgene band for normalization).As shown in Table 1, the experimental variation in the levelsof HBV replication between individual IRF^+/- and IRF^-/- miceand individual PKR^+/- and PKR^-/- mice was statistically significant(P values of 0.035 and 0.030, respectively), while no significantdifference was detected between RNase L^+/- and RNase L^-/- mice(data not shown). The levels of HBV replication observed inall groups of heterozygous control mice were comparable to thoseobserved in wild-type mice from lineage 1.3.32 (data not shown).The livers from the mice shown in Fig. 1 were also tested forthe expression of IFN- ${gamma}$ and 2',5'-OAS (a known IFN- ${alpha}$ /ß-inducibleenzyme that produces an activator of RNase L) (25) by an RPA.As expected, neither message was detected in these uninflamedlivers (data not shown), and similar results were obtained forsaline-injected controls from all lineages (Fig. 2 and 3). Nonetheless,the higher content of HBV replicative forms in IRF-1^-/- andPKR^-/- mice suggests that both of these pathways (perhaps inducedby undetectable amounts of interferons) appear to contributeindividually to the control of HBV replication in uninflamedlivers of wild-type mice.

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FIG. 1. Higher levels of HBV replication in the livers of IRF-1^-/- or PKR^-/- mice. Six age (8 to 10 weeks)-, sex (male)-, and serum HBeAg-matched mice that were either heterozygous or homozygous for the indicated null mutation were sacrificed, and the livers were harvested. Following extraction, total DNAs were pooled for each group and analyzed for HBV replication by Southern blot analysis. Bands corresponding to the integrated transgene (Trans.), relaxed circular (RC), and single-stranded (SS) linear HBV DNA replicative forms are indicated. The integrated transgene can be used to normalize the amount of DNA bound to the membrane. The filter was hybridized with a ³²P-labeled HBV-specific DNA probe.

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TABLE 1. Statistically significant experimental variation of the intrahepatic content of HBV replicative forms in mice heterozygous (plus/minus) or homozygous (minus/minus) for the IRF-1 or PKR null mutation^a

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FIG. 2. Role of IRF-1, RNase L, or PKR in antiviral activity induced by poly-I/C. Groups of age-, sex-, and serum HBeAg-matched transgenic mice (four mice per group) that were either heterozygous or homozygous for the indicated null mutation were injected intravenously with a single dose of poly(I-C) (200 µg/mouse) and sacrificed 24 h later. Total hepatic DNA was analyzed for HBV replication by Southern blot analysis. Bands corresponding to integrated transgene (Trans.), relaxed circular (RC), and single-stranded (SS) linear HBV DNA replicative forms are indicated. The integrated transgene can be used to normalize the amount of DNA bound to the membrane. Total hepatic RNA was analyzed for the expression of cytokine- and 2',5'-OAS-specific transcripts by an RPA. TNF, tumor necrosis factor; IL, interleukin. The RNA encoding ribosomal protein L32 was used to normalize the amount of RNA loaded in each lane. The results were compared with those observed for livers pooled from 10 age-, sex-, and serum HBeAg-matched transgenic littermates injected with saline (NaCl). The mean sALT activity, measured at the time of autopsy, is indicated for each group and is expressed in units per liter.

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FIG. 3. Role of IRF-1, RNase L, or PKR in antiviral activity induced by IFN- ${gamma}$ . Groups of age-, sex-, and serum HBeAg-matched transgenic mice (four mice per group) that were either heterozygous or homozygous for the indicated null mutation were injected intravenously with a single dose of IFN- ${gamma}$ (200,000 U/mouse) and sacrificed 24 h later. Total hepatic DNA was analyzed for HBV replication by Southern blot analysis. Bands corresponding to integrated transgene (Trans.), relaxed circular (RC), and single-stranded (SS) linear HBV DNA replicative forms are indicated. The integrated transgene can be used to normalize the amount of DNA bound to the membrane. Total hepatic RNA was analyzed for the expression of cytokine- and 2',5'-OAS-specific transcripts by an RPA. TNF, tumor necrosis factor; IL, interleukin. The RNA encoding ribosomal protein L32 was used to normalize the amount of RNA loaded in each lane. The results were compared with those observed for livers pooled from 10 age-, sex-, and serum HBeAg-matched transgenic littermates injected with saline (NaCl). The mean sALT activity, measured at the time of autopsy, is indicated for each group and is expressed in units per liter.

Role of IRF-1, RNase L, or PKR in antiviral activity induced by poly-I/C. To test the role of IRF-1, RNase L, or PKR in the antiviralactivity of IFN- ${alpha}$ /ß induced by poly(I-C) in IRF-1^-/-,RNase L^-/-, or PKR^-/- animals, groups of age-, sex-, and serumHBeAg-matched transgenic mice that were either heterozygousor homozygous for the respective null mutation were injectedintravenously with a single dose of poly(I-C) (200 µg/mouse).Mice were bled and sacrificed, and livers were harvested 24h later, when the antiviral activity of poly(I-C) is maximal(21, 29). Results were compared with those observed for liverspooled from six age-, sex-, and serum HBeAg-matched transgeniccontrols that were sacrificed 24 h after injection with saline.

As shown in Fig. 2, the hepatic content of HBV DNA replicativeforms was profoundly reduced in all groups of IRF-1, RNase L,or PKR heterozygous or homozygous transgenic mice after poly(I-C)injection compared to the respective saline-injected controlmice (as measured by phosphorimaging analysis, the average reductionof HBV DNA replicative forms was over 10-fold in all groupsof mice). The most significant reduction involved the single-strandedDNA forms, while the more mature, high-molecular-weight relaxedcircular double-stranded DNA forms remained detectable, albeitat levels lower than those detected in control mice (Fig. 2).The relative resistance of the mature HBV DNA forms to the antiviraleffect of poly(I-C) is consistent with previous studies thatshowed that poly(I-C) either destabilizes or inhibits the formationof HBV RNA-containing capsids (29). Under these circumstances,single-stranded DNA-containing capsids disappear after RNA-containingcapsids but before mature capsids, which are cleared from hepatocyteswith slower kinetics (29).

As also shown in Fig. 2, the signal transduction pathway(s)required for the poly-I/C-dependent induction of 2',5'-OAS RNAwas intact in all groups of mice. Furthermore, the absence ofdetectable levels of IFN- ${gamma}$ RNA in these same livers (Fig. 2)suggests that this cytokine did not mediate the antiviral effectof poly-I/C. This result is consistent with previous resultsshowing that the entire inhibitory effect of poly(I-C) in thissystem is mediated by IFN- ${alpha}$ /ß (21).

In keeping with the notion that poly(I-C) inhibits HBV replicationnoncytopathically (21), little or no liver disease was observedeither histologically (data not shown) or biochemically (Fig.2, bottom), as indicated by the very modest elevation in thelevel of sALT (a hepatocellular enzyme that is released intothe circulation by injured hepatocytes) at the time of autopsy.

Role of IRF-1, RNase L, or PKR in antiviral activity induced by IFN- ${gamma}$ . The intrahepatic induction of IFN- ${gamma}$ inhibits HBV replicationin transgenic mice (3, 10), and this effect occurs independentlyof IFN- ${alpha}$ /ß (21). IFN- ${gamma}$ and IFN- ${alpha}$ /ß bind todistinct surface receptors and activate multiple intracellularantiviral pathways, some of which are common and involve IRF-1,RNase L, or PKR (25). To monitor the role of IRF-1, RNase L,or PKR in the direct antiviral activity of IFN- ${gamma}$ , groups of animals(four mice per group) from the same lineages as those used inthe experiment shown in Fig. 1 were injected intravenously witha single dose of murine recombinant IFN- ${gamma}$ (200,000 U/mouse) andsacrificed 24 h after injection.

As shown in Fig. 3, HBV DNA replication was profoundly inhibitedin the different groups of IRF-1, RNase L, or PKR heterozygousor homozygous transgenic mice after IFN- ${gamma}$ injection comparedto the respective saline-injected controls (as measured by phosphorimaginganalysis, the average reduction of HBV DNA replicative formswas about 10-fold in all groups of mice, with the exceptionof RNase L^-/- mice, in which the reduction was about 6-fold).As in the experiment with poly-I/C, the inhibitory effect ofIFN- ${gamma}$ on HBV replication was associated with the intrahepaticinduction of 2',5'-OAS RNA (Fig. 3), although this effect wasless pronounced than that observed after poly(I-C) injection(Fig. 2), particularly for PKR^-/- mice (Fig. 3). The notionthat IFN- ${gamma}$ induces lower levels of 2',5'-OAS RNA than IFN- ${alpha}$ /ßwas previously demonstrated (24). Moreover, it was previouslyshown that the lack of the PKR gene results in a defect in IFN- ${gamma}$ -dependentsignaling (17). Again, little or no liver disease was observedeither histologically (data not shown) or biochemically (Fig.3, bottom).

In summary, the results reported here showed that unmanipulatedRNase L^-/- transgenic mice replicate HBV in the liver at levelssimilar to those in the respective controls. This result, coupledwith the fact that the deletion of RNase L activity does notblock the antiviral effect of poly(I-C) or IFN- ${gamma}$ , suggests thatRNase L is not likely to mediate the ability to inhibit HBVreplication. The results also showed that unmanipulated IRF-1^-/-or PKR^-/- transgenic mice replicate HBV in the liver at levelsslightly higher than those in the respective controls, suggestingthat, under basal conditions, IRF-1 or PKR appears to mediatesignals that modulate HBV replication. Follow-up experimentsshowed that the antiviral effect of poly(I-C) or IFN- ${gamma}$ was fullyoperative in the absence of either IRF-1 or PKR. Although therewas a defect in IFN- ${gamma}$ induction of 2',5'-OAS in the PKR^-/- mice,the antiviral activity of IFN- ${gamma}$ was intact. Since 2',5'-OAS isupstream of RNase L, these results are in accord with the lackof constitutive or induced anti-HBV activity in the RNase L^-/-mice. Collectively, the data suggest either that high localconcentrations of IFN- ${alpha}$ /ß or IFN- ${gamma}$ inhibit HBV replicationby activating IRF-1 or PKR or that other IFN-inducible pathwaysmediate their antiviral effects. Future experiments with bothIRF-1^-/- and PKR^-/- HBV transgenic mice will attempt to discriminatebetween these two hypotheses.

In keeping with the possibility that other IFN-inducible genesare involved, it is noteworthy that the advent of oligonucleotidearrays has enabled investigators to identify many novel genesthat are induced or repressed by IFN- ${gamma}$ or IFN- ${alpha}$ /ß (6,7). Furthermore, it was recently shown that although EMCV issusceptible to the antiviral activity of either RNase L or PKR,the simultaneous disruption of both gene products is still associatedwith residual IFN-dependent antiviral activity (33); this resultindicates that as-yet-undefined IFN-inducible antiviral pathwaysare operative in the control of EMCV. It is also worth mentioningthat the Mx protein, an IFN-induced GTPase that selectivelyinhibits influenza viruses and bunyaviruses (12), is not involvedin our system, since the genetic backgrounds (C57BL/6 and 129/Sv)of the mice used here are deficient for this particular protein(25). Future research aimed at further defining IFN-inducedintracellular molecular events that control HBV is clearly warranted.

ACKNOWLEDGMENTS

We thank Monte Hobbs for providing the cytokine gene probesused in the RPA experiments and Margie Chadwell for excellenttechnical assistance.

This work was supported by grants AI40696 (to L.G.G.), CA40489(to F.V.C.), AI34039 (to B.R.G.W.), and CA44059 (to R.H.S.)from the National Institutes of Health.

FOOTNOTES

* Corresponding author. Mailing address: The Scripps Research Institute, Department of Molecular and Experimental Medicine, 10550 N. Torrey Pines Rd., La Jolla, CA 92037. Phone: (858) 784-2758. Fax: (858) 784-2960. E-mail: guidotti{at}scripps.edu.

Manuscript 14438-MEM from The Scripps Research Institute.

REFERENCES

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