Replication of a hepatitis A virus replicon detected by genetic recombination in vivo

Verena Gauss-Müller1 and Yuri Y. Kusov1

Institute of Medical Molecular Biology, Medical University of Lübeck, Ratzeburger Allee 160, D-23538 Lübeck, Germany1

Author for correspondence: Verena Gauss-Müller. Fax +49 451 500 3637. e-mail gaussmue{at}molbio.mu-luebeck.de


   Abstract
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Abstract
Introduction
Methods
Results
Discussion
References
 
Unlike other picornaviruses, hepatitis A virus (HAV) replicates so inefficiently in cell culture that the study of its RNA biosynthesis presents a major experimental challenge. To assess viral RNA replication independent of particle formation, a subgenomic replicon representing a self-replicating RNA was constructed by replacing the P1 domain encoding the capsid proteins with the firefly luciferase sequence. Although translation of the HAV replicon was as efficient as a similar poliovirus replicon, the luciferase activity derived from replication of the HAV construct was more than 100-fold lower than that of poliovirus. The replication capacity of the HAV replicon was clearly demonstrated by its ability to recombine genetically with a non-viable, full-length HAV genome that served as capsid donor and thus to rescue a fully infectious virus. In contrast to a replication-deficient replicon, co-expression of the genetically marked and replication-competent HAV replicon with several lethally mutated HAV genomes resulted in the successful rescue of infectious HAV with a unique genetic marker. Our data suggest: (i) that autonomous HAV RNA replication does not require sequences for the HAV structural proteins; and (ii) that low-level genome replication can unequivocally be demonstrated by the rescue of infectious virus after co-expression with non-viable genomes.


   Introduction
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Abstract
Introduction
Methods
Results
Discussion
References
 
Genetic exchange by homologous and non-homologous recombination is a phenomenon common among RNA viruses and may lead to hybrid or defective interfering RNA molecules (Lai, 1992 ; Nagy & Simon, 1997 ). Hybrid products containing the genetic information of more than one molecular species have evolutionary significance for this class of virus and are the basis of virus genetic diversity. Although recombination has also been observed with non-replicating genomes (Gmyl et al., 1999 ), in the most common and biologically relevant mechanism of recombination, non-contiguous RNA molecules are joined by an actively copying RNA polymerase that switches from one template to another during negative-strand synthesis (copy-choice; Kirkegaard & Baltimore, 1986 ; Jarvis & Kirkegaard, 1992 ). Models for the mechanism of template switching and the role of template signals, such as sequence or secondary structures, have been proposed (Kim & Kao, 2000 ).

Similar to other positive-strand RNA viruses, the picornaviral genome serves as template for both translation and replication. Initially, the viral RNA is translated into a polyprotein (P1–P2–P3), which is cleaved into the mature viral proteins by virus-encoded proteinases, making picornaviral gene expression mostly dependent on polyprotein processing. The viral structural proteins, VP1, VP2, VP3 and VP4, are released from their common precursor, P1. In a regulated fashion, the non-structural proteins, including the viral proteinase (3C) and polymerase (3D), are liberated from domains P2 and P3 of the polyprotein and are the major constituents of the virus replication complex (RC), which catalyses RNA genome replication. Once the RC is formed, viral RNA is used as the template for replication, which proceeds in the opposite direction to translation and most likely competes with it (Gamarnik & Andino, 1998 ). In addition to the viral proteins, cis-acting replication elements (CRE) on the viral RNA are essential for the formation of the RC and thus for viral genome replication. Involvement of individual viral and host components in this process has been investigated using either an in vitro translation/replication system (Molla et al., 1991 ; Barton & Flanegan, 1993 ) or viral replicons encoding a reporter gene in place of the viral capsid proteins. Autonomous replication of the replicon can be followed by measuring the increment of its reporter gene activity (Andino et al., 1993 ).

Among the picornaviruses, hepatitis A virus (HAV) is unique in its protracted replication in cell culture. Weak translation initiation, protein processing, asynchronous uncoating and lack of host shutoff have all been suggested to contribute to this behaviour (Bishop & Anderson, 2000 ; Funkhouser et al., 1999; Jia et al., 1998; Michel et al., 2001 ). Furthermore, nothing is known about the activity of either the HAV polymerase (3Dpol) or the molecular constituents of the virus RC. In order to assess HAV genome replication, we have constructed a replicon that lacks the genomic region of the structural proteins (P1) and encodes a reporter gene instead. As the replication capacity of the HAV replicon was found to be very poor in comparison with a replicon of poliovirus (PV), the prototype picornavirus (Andino et al., 1993 ), its replication competence was demonstrated by the successful genetic recombination of the replicon with several non-viable HAV genomes, which encoded the capsid proteins as selection markers. Recombination resulted in infectious HAV particles. In contrast, a replication-deficient replicon was unable to produce infectious virus when co-expressed with P1-encoding non-viable HAV genomes. With the aid of the sensitive rescue system described here, we provide evidence that even very low levels of genome replication can be made detectable after genetic recombination.


   Methods
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Abstract
Introduction
Methods
Results
Discussion
References
 
{blacksquare} cDNA constructs.
An HAV replicon (pT7-18f-LUC) was constructed by replacing the HAV P1 domain within the XbaI (nt 727 of the HAV strain HM175 18f, GenBank accession no. M59808) and SacI (nt 2972) restriction sites by a PCR product of the firefly luciferase gene flanked by NheI and SacI restriction sites. After ligation of the PCR-amplified and restricted luciferase gene into pT7-18f (Kusov & Gauss-Müller, 1999 ) linearized by XbaI and SacI, pT7-18f-LUC was created encoding an open reading frame with luciferase flanked by the first four amino acids of the HAV polyprotein and by 12 C-terminal amino acids of VP1 and followed by the P2 and P3 domains of the HAV polyprotein (Fig. 1, upper panel, B). To generate a replication-deficient replicon (pT7-18f-LUCmut), the unique XhoI site at nt 6983 was mutated after restriction with XhoI, filling in the overhangs with Klenow enzyme and religation (Fig. 1, upper panel, C). To genetically mark the replicon, ClaI (italics) and Bsp1407I (underlined) restriction sites were introduced adjacent to the unique XhoI site (bold), using a mutagenesis primer (5' gttttaatagttttctctcgagatgtAcagatCgataatcttgatttgat 3') with two exchanged nucleotides (capital letters). Note that an additional Bsp1407I site is located at nt 6873 of the HAV genome of strain 18f. The poliovirus replicons used were a generous gift from R. Andino (Andino et al., 1993 ): pRluc-31 encodes the wild-type sequence of poliovirus type 1 and pRluc-181 has a mutation in the RNA-binding domain of proteinase 3C and is replication-deficient. Luciferase T7 control DNA (pT7-LUC) (Promega) was used as a control.



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Fig. 1. Upper panel: Schematic representation of the cDNA constructs used. Various complete non-viable HAV genomes (A) that carry lethal mutations within the viral polyprotein served as recombination acceptor and capsid donor in the recombination assay: {downarrow}, locations of cleavage-site mutations within P3, {blacktriangleup}, deletion of VP4, *, truncation of 3D; +, mutation in the 3C RNA-binding site. See Methods for details of the constructs and Table 1 for nomenclature of the mutants. The replication-competent (pT7-18f-LUC) (B) and the replication-deficient (pT7-18f-LUCmut) (C) replicon carry the luciferase gene in place of the HAV P1 domain within the XbaI and SacI sites at nt 727 and 2972, respectively. In addition, genetic markers (ClaI and Bsp1407I as restriction sites) were inserted downstream of the unique XhoI restriction site. In the defective replicon (pT7-18f-LUCmut), a four-base insertion was placed in the XhoI site resulting in a frame-shift in protein 3D marked by the dotted box. Prior to in vitro transcription by T7 RNA polymerase, cDNAs were linearized with AatII located downstream of the poly(A) tail. The terminal non-coding regions of the genome are marked by narrow boxes; the truncated domain in C is dotted. Lower panel: scheme for detecting recombination products. HuhT7 cells that constitutively express T7 RNA polymerase were co-transfected with DNA of the capsid donor (A) and DNA of either the replication-competent (B) or -deficient replicon (C). Extracts of passage 0 were used for passage 1 to rescue the recombination product. Genetic recombination was analysed by ELISA and RT–PCR in passage 0 and 1. Only after co-expression with the replication-competent replicon was viable virus rescued.

 

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Table 1. Recombination between lethally mutated HAV genomes (acceptor) and the replication-competent (pT7-18f-LUC) and incompetent (pT7-18f-LUCmut) HAV replicon used as donor

 
{blacksquare} Lethal HAV mutants.
Some of the cDNA constructs encoding non-viable full-length HAV genomes due to lethal mutations in the P2 and P3 regions have been previously described (Kusov & Gauss-Müller, 1999 ). In one set of mutants (pT7-18f-3A/3Bm, pT7-18f-3B/3Cm, pT7-18f-3C/3Dm), 3C cleavage sites at junctions 3A/3B, 3B/3C and 3C/3D of the polyprotein, respectively (see Table 1 for the mutated amino acids, and Fig. 1, upper panel, A, for the location of the mutations in the polyprotein), were rendered uncleavable by site-directed mutagenesis (Kusov & Gauss-Müller, 1999 , and data not shown). A lethal frame-shift mutation in 3D of the full-length cDNA was introduced by filling in the overhangs of the unique XhoI site and religating the plasmid to yield pT7-18f-{Delta}3D. The RNA binding site of the viral proteinase 3C was mutated by exchanging amino acid residue 98 from D to N creating pT7-18f-3C-D98N) and pT7-18f-2{Delta}B has an in-frame deletion of 2B, thus rendering both genomes replication-deficient (data not shown). pT7-18f-{Delta}VP4 is deficient in capsid formation (Probst et al., 1999 ). All mutated cDNA fragments were confirmed by sequencing.

{blacksquare} RNA transcription in vitro and transfection.
Plasmid DNA was linearized with appropriate restriction enzymes and in vitro-transcribed with the MEGAscript system (Ambion), basically as described previously (Kusov & Gauss-Müller, 1999 ). RNA (1–10 µg) was transfected into HuhT7 or Bsc-1 cells by liposome transfection or electroporation, respectively. For lipofection, the RNA was mixed with 3 µl of DMRIE-C (Life Technologies) before it was applied to a monolayer of 105 cells grown on 3·5 cm2. After a 3 h incubation, the transfection mixture was replaced by medium containing 10% foetal calf serum. Incubation was continued for the time periods indicated without passaging the cells. For determination of luciferase activity, transfected cells grown on 3·5 cm2 were lysed with 200 µl of cell culture lysis buffer (Promega) at room temperature. Luciferase activity was measured using a MicroLumat P96 and substrates (Berthold Detection Systems) and expressed in relative light units (RLU).

{blacksquare} DNA transfection and recombination assay.
DNA transfection mix containing 1–4 µg of cDNA and 9 µl LipofectAmin (Life Technologies) in 200 µl OptiMEM (Life Technologies) was preincubated for 30 min at room temperature, diluted with OptiMEM to 1 ml and transferred to HuhT7 cells (5x105/10 cm2; Schultz et al., 1996 ). After incubation for 3 h at 37 °C, the transfection mix was replaced by growth medium containing geneticin (G418 sulfate, 400 µg/ml; Life Technologies). For in vivo recombination, acceptor and donor cDNA were mixed and transfected into HuhT7 cells, as depicted in Fig. 1 (lower panel). Transfected cells were incubated for 20 days (passage 0) without passaging, before extracts were harvested and tested for viral antigen, RNA and infectivity. In detail, transfected cells of multiple wells (10 cm2) were each harvested in 250 µl PBS containing 0·05% Tween-20 (PBS-Tw). After three cycles of freeze-thawing, the clarified supernatant was used for the detection of viral antigen (HAAg) by ELISA with the monoclonal antibody 7E7, as previously described (Kusov & Gauss-Müller, 1999 ; Probst et al., 1998 , 1999 ). For characterization of recombinant proteins, plasmid DNA was transiently expressed with the aid of vaccinia virus vTF7-3 (Elroy-Stein & Moss, 1990 ). Extracts of trans-infected cells were analysed by immunoblot, as previously described (Kusov & Gauss-Müller, 1999 ; Probst et al., 1998 , 1999 ). To determine the infectivity of the virus rescued by genetic recombination, the PBS-Tw extract was diluted 1:100 and used to inoculate HuhT7 cells grown in 25 cm2 flasks (passage 1). After 15–25 days of subpassage, infected cells were harvested and analysed by ELISA and RT–PCR.

{blacksquare} HAV RNA analysis by RT–PCR.
Total RNA from transfected cells, and of cells infected with HAV strain 18f or with the virus rescued by genetic recombination (passage 1), was extracted by Trizol (LifeTechnologies). The genomic regions between HAV nucleotides 5310 and 5830 (Fig. 3) and between nucleotides 5908 and 7393 (Fig. 6) were amplified using the C.therm. polymerase One-Step RT–PCR system (Roche, Applied Science) and appropriate HAV-specific primers. The latter amplification product of 1·5 kb was digested with either XhoI, ClaI or Bsp1407I and analysed on an agarose gel.



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Fig. 3. RNA stability and antigen production in cells transfected with RNA transcribed in vitro from pT7-18f (A) and pT7-18f-{Delta}2B (B). RNA was amplified by RT–PCR with a product of approximately 0·5 kb. Viral antigen accumulating in transfected cells was determined by ELISA.

 


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Fig. 6. Analysis of the genetic marker in the virus rescued after recombination. After recombination of the replication-competent replicon (donor) with the non-viable HAV genome derived from pT7-18f-{Delta}3D (acceptor), a part of the P3 domain of the viral RNA (1·5 kb) was amplified by RT–PCR. The RNA amplification product from cells infected with HAV strain 18f (lanes 2, 5, 8 and 11), cells co-expressing pT7-18f-LUC and pT7-18f-{Delta}3D (passage 0, lanes 1, 4, 7 and 10), and cells infected with the rescued virus (passage 1, lanes 3, 6, 9 and 12) were restricted with appropriate enzymes. Restriction patterns of co-transfected cells (passage 0) are a mixture derived from both in vivo transcripts. The cleavage pattern of ClaI (lanes 1–3) and Bsp1407I (lanes 4–6) is characteristic for the RNA of the genetically marked rescued virus (lanes 3 and 6) and is dissimilar to that of the wild-type (wt) HAV 18f (lanes 2 and 5). Note that due to the additional Bsp1407I site, three restriction fragments of 0·9, 0·4 and 0·2 kb are produced from the genetically marked genome (lane 6). Restriction by XhoI is a feature of both the wild-type (lane 8) and the rescued virus (lane 9) and is absent in the mutant RNA of pT7-18f-{Delta}3D, which is present in the sample depicted in lane 7. The unrestricted amplification product is 1·5 kb (lanes 10–12). Lane M shows the mobility of DNA markers indicated on the right.

 

   Results
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Abstract
Introduction
Methods
Results
Discussion
References
 
Expression of the HAV genome and replicon in vivo
To assess HAV genome replication, an HAV replicon (pT7-18f-LUC) was constructed by replacing the domain of the structural proteins (P1) with luciferase sequences (Fig. 1, upper panel, B). Firefly luciferase was chosen as the reporter gene because of its high enzymatic activity and its relatively short half-life. Since the genome of positive-strand RNA viruses functions as template for both protein and RNA synthesis, reporter gene activity of an active replicon mirrors the sum of the translation products derived from input and progeny RNA generated during genome replication. To distinguish the luciferase activity of newly synthesized RNA molecules from that of input RNA, reporter gene activity of a replication-competent replicon (Fig. 1, upper panel, B) was compared with that of a replication-deficient replicon, which encoded a truncated and thus inactive polymerase (Fig. 1, upper panel, C).

In an initial experiment to assess the overall amplification competence of the HAV replicon, the kinetics of reporter gene expression for the replication-competent and -deficient replicons of HAV and poliovirus (PV) were compared after transfection of HuhT7 cells with equal amounts of run-off transcripts. Similar to comparable PV replicons whose expression kinetics have been shown elsewhere (Andino et al., 1993 ), maximal luciferase activity of the HAV replicons was reached approximately 15 h post-transfection (p.t.) under the applied conditions. Similarly, as reported recently (Yi & Lemon, 2002 ), luciferase activity of the replication-competent HAV replicon was detectable up to 72 h p.t. (not shown). For a quantitative assessment of their function in translation and replication, the luciferase activities expressed from the replication-deficient HAV (pT7-18f-LUCmut) and PV (pRLuc-181) replicons were compared with the respective replication-competent replicons (Fig. 2A). Whereas the replication-competent PV replicon (pRLuc-31) reached more than 100-fold higher levels than the deficient PV replicon (pRLuc-181) within 15 h of expression, the luciferase activity of the replication-competent HAV replicon (pT7-18f-LUC) was only 20% higher than that of the replication-deficient replicon (pT7-18-LUCmut). The luciferase activities of both deficient replicons were of the same order of magnitude. At later time-points (40–60 h p.t.), the luciferase activity of the replication-competent HAV replicon was up to twofold higher than that of the replication-deficient replicon (not shown). These results clearly indicate that only a small fraction of the luciferase activity is translated from replicated HAV RNA and that the majority of reporter activity originates from translation of input RNA. Although we cannot completely rule out the possibility that PV and HAV RNA differ in their half-lives, our data are in accordance with other reports that showed similar translation efficiencies of the replication-deficient PV and HAV replicons in cell culture (Bergamini et al., 2000 ; Michel et al., 2001 ).



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Fig. 2. Luciferase activity produced in cells transfected with replicon RNA and expression of proteins. (A) Comparison of luciferase activity produced from HAV and PV replicons at 15 h p.t. with RNA transcribed from the replication-competent and -deficient poliovirus replicons pRLuc-31 and pRluc-181, respectively (Andino et al., 1993 ), and the corresponding HAV replicons, pT7-18f-LUC and pT7-18f-LUCmut. Statistical significance is expressed by P values. (B) Proteolytic processing pattern of the HAV replicons. Cells expressing cDNA of either the replication-competent HAV replicon (pT7-18f-LUC; lanes 1 and 4), the replication-deficient replicon (pT7-18f-LUCmut; lanes 2 and 5), or the complete HAV genome (pT7-18f; lanes 3 and 6) were analysed by immunoblot with anti-2A (lanes 1–3) and anti-3C (lanes 4–6) antibodies. No immunoreactive proteins were detected in non-transfected cells (not shown). Immunoreactive proteins are marked on the right and the molecular mass standard on the left. Two forms of polypeptide 3ABC are formed (Probst et al., 1998 ).

 
To determine whether the low replication level of the HAV replicon might be explained by inefficient liberation of the viral non-structural proteins from the polyprotein and in consequence by the slow formation of the viral RC in the presence of the luciferase sequences, proteolytic processing of the replicon and the complete HAV polyprotein were compared. cDNAs encoding the replication-competent replicon, the replication-deficient replicon or the complete HAV genome were expressed with the aid of the recombinant vaccinia virus vTF7-3, which substantially enhances protein synthesis and allows visualization of the processed proteins by immunoblot (Elroy-Stein & Moss, 1990 ; Kusov & Gauss-Müller, 1999 ; Probst et al., 1998 , 1999 ). Based on the proteolytic processing pattern detected by anti-2A and anti-3C sera, the efficiency of 3C-mediated proteolytic cleavage of the HAV polyprotein was judged (Kusov & Gauss-Müller, 1999 ; Probst et al., 1998 ). The absolute and relative amounts of 3C-containing polypeptides (3ABC, 3BC, 3C) were equal in the extracts expressing either the HAV replicons or the full-length genome (Fig. 2B, lanes 4–6). Instead of P1–2A and VP1–2A derived from the complete genome (Fig. 2B, lane 3), the luciferase–2A fusion protein (70 kD) produced by both HAV replicons was identified by the anti-2A serum (lanes 1 and 2). The data on the proteolytic processing of the replicon’s P3 domain clearly argue for the correct formation of the RC, even in the presence of the luciferase, and suggest that inadequate release of the virus replication proteins is not the reason for inefficient replication of HAV RNA.

Besides other limiting steps in the virus life-cycle, inefficient and slow HAV RNA replication might contribute to the overall protracted infectious cycle of HAV in cell culture. To assess directly the onset of viral RNA biosynthesis, synthetic transcripts derived from cDNA containing the complete viral genome (Fig. 1, upper panel, A) were transfected into cells and RNA and capsid synthesis were followed by RT–PCR and ELISA, respectively. A replication-deficient genome transcribed from a mutated cDNA (pT7-18f-{Delta}2B) was used as control for the half-life of the input RNA. Whereas the transfected non-viable HAV RNA derived from pT7-18f-{Delta}2B was degraded and no longer detectable by RT–PCR 3 days p.t. (Fig. 3B), newly synthesized viral RNA produced from infectious RNA was detectable in increasing levels starting 4 days p.t. (Fig. 3A). Viral RNA synthesis was paralleled by antigen production. Combining these data on the relatively short half-life of transfected RNA and the delayed onset of viral RNA synthesis, it can be concluded that the study of HAV RNA replication is severely compromised, if not impossible, when RNA replication is initiated by short-lived in vitro RNA transcripts.

Replication of the HAV replicon after DNA transfection
In order to compensate for the rapid loss of transfected RNA molecules and based on the fact that the biological half-life of transfected DNA is much longer than that of synthetic RNA (Graeber et al., 1998 ), we next assessed replicon amplification after transfecting cDNA into HuhT7 cells. These cells constitutively express T7 RNA polymerase (Schultz et al., 1996 ) and therefore allow the sustained in situ production of HAV RNA with high structural fidelity. The cells are susceptible to HAV infection and have been used to rescue infectious HAV from cDNA and RNA with equal efficiency (Kusov & Gauss-Müller, 1999 , and unpublished observation). As shown in Fig. 4, the reporter gene activity of both competent and incompetent HAV replicons increased in parallel for about 20 h p.t. Whereas the activity of the incompetent replicon slowly decreased over the next 100 h, the activity of the replication-competent HAV replicon reached a peak about 70 h p.t. The data clearly show that amplification of the HAV replicon can be demonstrated after DNA transfection in appropriate cells. Through in vivo production of replicon RNA, a prolonged supply of templates for both translation and replication is produced, which might be an essential prerequisite for weakly replicating RNA to be rescued by recombination (see below). In addition, the data imply that the HAV P1 region is not required for autonomous HAV genome amplification and apparently does not contain a cis-active replication RNA element.



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Fig. 4. Luciferase activity of HAV replicons pT7-18f-LUC and pT7-18f-LUCmut following DNA transfection into HuhT7 cells.

 
Rescue of infectious HAV after co-expression of the HAV replicon with non-viable HAV genomes encoding the structural proteins
In recent years, evidence has accumulated suggesting that genome recombination of positive-strand RNA viruses depends on ongoing genome replication and occurs during negative-strand synthesis (Jarvis & Kirkegaard, 1992 ; Lai, 1992 ). To explore further the replication competence of the HAV replicon, we tested its ability to recombine genetically with a non-viable acceptor genome. Non-viable, complete HAV genomes that encode the P1 domain as a phenotypic and selection marker and carry lethal mutations in the non-structural domain of the polyprotein were used as acceptors of recombination. The successful recombination event was demonstrated by the rescue of infectious virus that was able to spread from cell to cell. We reasoned that infectivity would only be recovered after replication-dependent, genetic recombination involving two genomes. One genome (recombination acceptor) encodes the genetic information for the capsid proteins (P1), but has a defect in the non-structural proteins; the other genome produces an active RC, but lacks the genetic information for capsid formation and thus the ability to spread in cell culture (recombination donor). DNA-transfected cells were used to demonstrate recombination since, in this experimental set-up, a sufficiently sustained supply of functional in vivo transcripts was produced compared with transfected RNA (see above). According to a previous report, recombination of extrachromosomal plasmid DNA can be excluded (Evans et al., 1988 ). HuhT7 cells were co-transfected with equal amounts of cDNA encoding the HAV replicon (pT7-18f-LUC) as donor and pT7-18f-3C/3Dm as acceptor, which encodes a non-viable HAV genome due to the mutated 3C/3D cleavage site (see experimental design in Fig. 1, lower panel). As a negative control, co-transfection was performed with the replication-deficient HAV replicon (pT7-18f-LUCmut) as donor. At various time-points p.t., cell extracts were prepared and tested for luciferase activity, HAV antigenicity and infectivity to prove rescue of replication-competent and packaged HAV genomes. As evidenced by the appearance of HAV antigenicity and infectivity (Fig. 5), viable virus was rescued after co-expression of the replication-competent HAV replicon with pT7-18f-3C/3Dm. No HAV antigenicity was detected and no infectious virus was rescued after co-transfection with pT7-18f-LUCmut. pT7-18f-3C/3Dm did not produce infectious HAV when transfected alone or after transfecting its RNA (data not shown). As already described above, luciferase activity was detectable up to day 4 after cDNA transfection of either replicon construct, indicating the production and translation of the in vivo-formed T7 transcripts. Lack of luciferase activity at the time of detectable HAV antigenicity indicates that packaging of the replicating replicon by the rescued virus did not occur (Jia et al., 1998 ). These results show a clear and direct correlation between the rescue of viable virus and the replication-competent replicon, implicating genomic recombination.



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Fig. 5. Kinetics of the production of HAV antigenicity (HAAg) after recombination of the replication-competent and -deficient HAV replicons with a non-viable HAV genome. Extracts of HuhT7 cells were harvested at various times after co-transfection of the cells with cDNA of the non-viable construct pT7-18f-3C/3Dm with either pT7-18f-LUC or pT7-18f-LUCmut. Extracts were tested for HAV antigenicity by ELISA (lower panel) and infectivity by subpassage (upper panel). After subpassaging in HuhT7 cells for 20 days, only extracts obtained 14 days post-co-transfection with the replication-competent replicon were found to contain infectious virus (+). The infectivity of extracts obtained 2–6 days p.t. was not determined (nd).

 
To prove directly that the rescued virus was the product of genetic recombination of two HAV genomes and to rule out contamination by wild-type virus, we made use of a genetic marker specific for the viral replicon. Two silent point mutations were introduced into the replicon cDNA near the 3' end, which resulted in unique restriction sites (see Fig. 1, upper panel, and the sequence of the mutagenesis primer). After co-transfecting the cDNA of the genetically marked replicon along with pT7-18f-{Delta}3D lacking the XhoI restriction site at position 6983 and encoding a truncated protein 3D, rescue of infectious virus was shown by HAV ELISA and by determining its infectivity. Furthermore, RT–PCR of the genomic region encompassing the genetic marker (nt 5908–7393) and subsequent restriction of the amplification product with XhoI, ClaI and Bsp1407I was performed using the total RNA fraction extracted from transfected cells. In addition to cells harvested 20 days p.t. (passage 0), cells obtained after the first viral passage (passage 1, 15 days post-infection) were used. After digestion of the PCR products with ClaI, the genetically marked RNA was clearly distinguishable from the uncleavable acceptor sequences (1·5 kb fragment, Fig. 6, lanes 2, 10, 11, 12) with two restriction fragments of 0·4 and 1·1 kb (lanes 1 and 3). In Fig. 6 (lane 1), the amplification product derived from total RNA from the transfected cells shows the restriction pattern derived from both genomes, one of which (pT7-18f-LUC) was cleavable with ClaI, whereas the other (pT7-18f-{Delta}3D) was not. After one passage of the rescued virus, only the restriction pattern of the genetically marked genome could be seen (lane 3). The restriction pattern of the input acceptor genome containing no genetic marker (shown in lane 2) was no longer detectable, clearly showing that there was no contamination with wild-type virus. This was further confirmed by the Bsp1407I restriction pattern, which again showed a mixture of fragments derived from both input templates in the RNA of transfected cells (lane 4), but clearly showed only the pattern of the genetically marked genome after one subpassage of the rescued virus (lane 6). The XhoI restriction pattern showed that in both the wt (lane 8) and the rescued virus (lane 9), the XhoI cleavage was present, whereas transfected cells contained templates both with and without this site (lane 7). Thus, the unequivocal identification of the genetic marker in the rescued virus provided direct evidence that recombination between the genomes of the replication-competent replicon and the non-viable viral mutant had occurred.

In a first assessment of the recombination crossover point, we tested various mutants for their ability to be rescued after co-expression with the replication-competent replicon. Based on our earlier work, we were interested in investigating non-viable mutants encoding polyproteins that are not processed at the 3C cleavage sites within the P3 domain (Kusov & Gauss-Müller, 1999 ). In addition, we used pT7-18f-{Delta}VP4, pT7-18f-{Delta}3D and pT7-18f-3C-D98N as recombination acceptors, in which either VP4 was deleted, 3D was truncated, or the putative 3C RNA binding site was mutated, respectively. In Fig. 1 (upper panel, A), the locations of the lethal mutations in the HAV genome are marked. Table 1 lists the mutants that were co-expressed with both the replication-competent and -deficient donor replicon. Recombination was determined by subpassaging extracts of the transfected cells, followed by RNA amplification and restriction analysis of the P3 region. In none of the co-expression experiments with the replication-deficient replicon pT7-18f-LUCmut was a viable virus detected, again providing clear evidence that recombination directly correlates with the replicon's replication competence. Recombination with the HAV replicon pT7-18f-LUC occurred with all tested genomes that were defective in their polyprotein cleavage. HAV genomes carrying mutations in the RNA binding site of protein 3C or truncated in 3D also underwent recombination with the replicon, whereas the genome with a deletion of VP4 could not be rescued. This latter result is in line with our earlier observation that an HAV genome lacking VP4 is defective in particle formation and thus non-viable (Probst et al., 1999 ). In conclusion, complete HAV genomes with an intact P1 domain, but carrying mutations in domain P3 can be rescued by recombination with an actively replicating replicon. Further experiments are necessary to map the crossover site in more detail.


   Discussion
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Abstract
Introduction
Methods
Results
Discussion
References
 
The study of autonomously replicating genomes has greatly enhanced the understanding of RNA replication of members of the Picornavirus family. The reporter gene activity of a picornaviral replicon is translated from both the RNA transfected into cells (input) and the progeny molecules produced by RNA replication. Therefore, the use of replicons allows the study of both virus translation and replication, two steps in the virus life-cycle tightly coordinated in vivo in space and time. By comparison with similar replicon constructs of PV, we clearly showed that translation initiated from transfected replication-deficient HAV or PV RNA is of the same order of magnitude (Fig. 2A). The same observation was made when transfected DNA was used to prime the in vivo expression of PV and HAV replication-deficient replicons (not shown). As translation rates are mostly regulated by initiation, our data clearly indicate that the internal ribosomal entry sites (IRES) of HAV and PV are equally efficient in vivo in the cells used. Earlier observations of relatively lower activity of the HAV IRES compared with that of poliovirus or encephalomyocarditis virus seem to be due to differences between the experimental systems used (Funkhouser et al., 1999 ; Whetter et al., 1994 ).

Various steps in the virus life-cycle, including uncoating, translation initiation and particle maturation, are thought to contribute to the restricted replication of HAV in cell culture, a striking feature that distinguishes the Hepatoviruses from other genera of the Picornaviridae. Here we provide experimental proof that HAV RNA replication is inefficient and delayed, as evidenced by the in vivo amplification of a replicon and the complete HAV RNA, and might therefore restrict the overall HAV life-cycle. By sensitive RT–PCR, de novo-synthesized RNA could be clearly distinguished from input RNA (Fig. 3). Furthermore, low but extended luciferase activity was observed after transfection of either HAV replicon RNA or DNA (Fig. 4). This is in accordance with a recent report (Yi & Lemon, 2002 ) showing that the replication-dependent luciferase activity of an HAV replicon reaches maximal levels 70 h p.t. It can be hypothesized that maximal translation precedes RNA biosynthesis by several hours and possibly with little temporal overlap. In contrast to the HAV replicon, the expression kinetics reported for PV replicons clearly showed that the reporter activity translated from input RNA was surpassed by reporter activity derived from progeny RNA (Andino et al., 1993 ) within a few hours p.t. The delayed onset and low efficiency of HAV RNA replication might be due to an inefficient template switch from translation to replication (Gamarnik & Andino, 1998 ). Only a small portion of HAV RNA either transfected into cells or in vivo-transcribed from transfected DNA seems to be used as template for negative-strand synthesis with the RNA serving primarily and mostly as template for translation. We favour the notion that RNA synthesis is both poorly initiated and proceeds in a rather inefficient manner. For HAV, neither the putative steps regulating the template switch (e.g. specific binding of viral and host proteins at the 5' end of viral RNA, circularization of the RNA genome) nor the activity of the HAV RC and its components (e.g. 3Dpol) itself have been addressed at the molecular level.

The biological half-life of transfected in vitro RNA transcripts is limited due to unspecific intracellular RNA degradation, and thus their functioning as templates for translation and replication is impaired. As demonstrated in Fig. 3, the apparent half-life of transfected HAV RNA is shorter than the lag period after which significant RNA replication can be detected. In contrast, transfected DNA is highly stable and functional in transcription for several days p.t. (Graeber et al., 1998 ). For viral and non-viral cDNAs, we confirmed the long-term expression of T7-promoted genes in cells either constitutively expressing T7 RNA polymerase or infected with a helper virus expressing T7 RNA polymerase (e.g. vaccinia virus MVA-T7; Kusov et al., 2002 ). Besides its longer biological half-life, it can be assumed that the RNA in vivo-transcribed from transfected DNA has improved translation efficiency compared with transfected RNA that had been produced by in vitro transcription. In order to circumvent the conflict of low RNA stability with the delayed onset of RNA replication, DNA transfection was used for the studies on genetic recombination. This experimental approach is also supported by a report that emphasizes the need for sufficiently high concentrations of RNA for recombination (Kirkegaard & Baltimore, 1986 ). As deduced from detailed studies described earlier (Evans et al., 1988 ), plasmid DNA recombination does not occur due to the lack of extrachromosomal DNA polymerization. Our recombination experiments showed a direct correlation between the rescue of viable virus and the replication competence, clearly indicating that the genetic recombination is an event tightly associated with replication.

A model for the in vivo HAV recombination system presented here is shown in Fig. 7 with the rescued genetically marked genome in the middle. Assuming homologous recombination as the most common mechanism, and based on studies on poliovirus (Jarvis & Kirkegaard, 1992 ), we propose that during negative-strand synthesis, the RC formed after translation of the donor RNA (replicon) switches templates and continues to copy the acceptor RNA encoding capsid proteins. In contrast to recombination systems described elsewhere (Duggal et al., 1997 ; Tang et al., 1997 ), we identified the recombination product by its ability to form viral particles, i.e. its competence to complete the full virus life-cycle and to spread from cell to cell. This property is a crucial prerequisite for the analysis of HAV replication described here, since the detection of newly formed viral genomes has been difficult under single-cycle growth conditions (Beard et al., 2001 ).



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Fig. 7. Model of recombination between the replication-competent, genetically marked (M) replicon (lower line) and a non-viable HAV genome carrying a lethal mutation (X) in the P3 domain (upper line). The non-viable HAV genome (dotted line) encoding the domain of the structural proteins (P1) serves as recombination acceptor, the replicon with the luciferase (LUC) sequence (solid line) is the recombination donor providing an active replication complex and the initial template for replication. In the middle, the genome of the recombination product containing the capsid domain P1 and the genetic marker (M) is shown as a chimera. On the right side, features of the genomes are shown. Whereas the acceptor and the rescued virus are competent (+), the donor (replicon) is deficient (-) in particle formation (as determined by ELISA). Conversely, the donor and the rescued HAV are replication-competent (+) and the acceptor genome is non-viable (-) due to the mutation in P3.

 
Recombination is a frequent and important mechanism in the evolution of RNA viruses since it fosters virus survival under unfavourable environmental conditions. As only one serotype of HAV is known so far and defined conditional HAV mutants are not available, recombination of this virus has been difficult to demonstrate. Defective HAV genomes have been described with large deletions in the P1 domain that may have been the product of recombination (Nuesch et al., 1989 ). Similarly, defective genomes of poliovirus are generated in cell culture, the replication of which interferes with replication of full-length viral genomes (Nomoto et al., 1979 ; Wimmer et al., 1993 ). Our finding that HAV RNA lacking the P1 domain is able to replicate autonomously supports the general view of the picornaviral genome bearing both terminal and internal cis-acting replication elements (CRE) and indicates that all non-structural proteins are required in cis for RNA replication. Further studies are under way to locate the HAV CRE within domains P2 and P3. In summary, we have shown here that the weak replication activity of the HAV replicon can be monitored by its competence to rescue viable virus from lethal mutants. This rescue system may be useful to show genome replication of other slowly replicating RNA viruses.

We thank B. Kölsche for excellent technical assistance and R. Andino for the poliovirus replicons. pT7-18f-{Delta}2B was provided by M. Jecht. We are grateful to S. Lemon for HuhT7 cells and to T. Morris for critical reading of the manuscript. This work was supported by a grant (SFB 367, project B7) from the Deutsche Forschungsgemeinschaft (DFG).


   References
Top
Abstract
Introduction
Methods
Results
Discussion
References
 
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Received 28 February 2002; accepted 8 May 2002.