Translation of hepatitis A virus RNA in vitro: aberrant internal initiations influenced by 5' noncoding region

Complete coding sequence and molecular analysis of hepatitis A virus from a chimpanzee with fulminant hepatitis

BACKGROUND

Hepatitis A virus (HAV) infects both humans and non-human primates, in experimentally infected chimpanzees is typically milder than in humans. In 1982, Abe and Shikata reported a first case of a chimpanzee with fulminant hepatitis caused by spontaneous HAV infection, and the underlying mechanisms of the disease remain unknown.

METHODS

To characterize denoted CFH-HAV, we conducted cloning and near full-length sequence analysis.

RESULTS

Phylogenetic analyses of VP1-2A and complete sequence comparison between various genotypes and the sample sequence showed clustering in genotype IB. Based on BLAST analysis, the sequence was most closely related to the wild-type (HM175/WT) isolate. Amino acid and nucleic acid similarities were 99.8% and 94.41%, respectively.

CONCLUSIONS

The chimpanzee may have been infected with human HAV genotype IB. The substitutions in VP2, VP4, 2B, 2C, and 3D, which may enhance virus proliferation, contributed to disease severity culminating in fulminant hepatic failure.

Adequate system for studying translation initiation on the human retrotransposon L1 mRNA in vitro

Unlike vertebrates and RNA-containing viruses, the objective estimate of molecular clock for DNA-containing viruses was so far absent. An extended central conservative genomic region of orthopoxviruses (about 102 kbp) and the sequence of DNA polymerase gene (about 3 kbp) of the viruses belonging to various genera from the family Poxviridae were analyzed. During this analysis, the known dating of variola virus (VARV) transfer from West Africa to South America (XVI century) and our own data on close phylogenetic relations between the modem West African and South American VARV isolates were used. As a result of this work, it was calculated for the first time that the rate of mutation accumulation in these DNA-containing viruses amounted to 0.9-1.2 x 10(-6) substitutions per site per year. The poxviruses started separating from the ancestor virus to form the modem genera approximately 500 thousand years ago; the ancestor of the genus Orthopoxvirus separated about 300 thousand years ago; and its division into the modem studied species took place approximately 14 thousand years ago.

Signals in hepatitis A virus P3 region proteins recognized by the ubiquitin-mediated proteolytic system

The hepatitis A virus 3C protease and 3D RNA polymerase are present in low concentrations in infected cells. The 3C protease was previously shown to be rapidly degraded by the ubiquitin/26S proteasome system and we present evidence here that the 3D polymerase is also subject to ubiquitination-mediated proteolysis. Our results show that the sequence (32)LGVKDDWLLV(41) in the 3C protease serves as a protein destruction signal recognized by the ubiquitin-protein ligase E3alpha and that the destruction signal for the RNA polymerase does not require the carboxyl-terminal 137 amino acids. Both the viral 3ABCD polyprotein and the 3CD diprotein were also found to be substrates for ubiquitin-mediated proteolysis. Attempts to determine if the 3C protease or the 3D polymerase destruction signals trigger the ubiquitination and degradation of these precursors yielded evidence suggesting, but not unequivocally proving, that the recognition of the 3D polymerase by the ubiquitin system is responsible.

Hepatitis A virus polyprotein processing by Escherichia coli proteases

Hepatitis A virus (HAV) encodes a single polyprotein, which is post-translationally processed. This processing represents an essential step in capsid formation. The virus possesses only one protease, 3C, responsible for all cleavages, except for that at the VP1/2A junction region, which is processed by cellular proteases. In this study, data demonstrates that HAV polyprotein processing by Escherichia coli protease(s) leads to the formation of particulate structures. P3 polyprotein processing in E. coli is not dependent on an active 3C protease: the same processing pattern is observed with wild-type 3C or with several 3C mutants. However, this processing pattern is temperature-dependent, since it differs at 37 or 42 degrees C. The bacterial protease(s) cleave scissile bonds other than those of HAV; this contributes to the low efficiency of particle formation.

Molecular biology of hepatitis A virus: significance of various substitutions in the hepatitis A virus genome

Hepatitis A virus (HAV) is the sole member of the hepatogenus of Picorna viridae. This virus can now be propagated in cell culture and in primates. Molecular biological studies of HAV have disclosed its genomic structure and the functional significance of the viral proteins to some extent. Hepatitis A virus has a positive-stranded RNA of approximately 7.5 kb that encodes a large polyprotein. Translation of the protein is influenced by the function of the internal ribosomal entry site in the 5' non-translating region. It is generally agreed that the polyprotein is processed to four structural and seven non-structural proteins by the proteinase encoded in the 3C region. Replication efficiency seems to be controlled by amino acid substitutions in the 2B and 2C regions. The virulence of HAV in primates may be determined by substitutions in the 2C region. Although the severity of hepatitis A was thought to be determined by immunological reactions of the host to the virus, the potential virulence of the variant viruses themselves may need further examination. Recent progress in polymerase chain reaction technology has made possible an analysis of the HAV sequence in clinical specimens; such analysis is of importance in the disclosure of differences in HAV subspecies in different clinical conditions.

Hepatitis A virus capsid protein VP1 has a heterogeneous C terminus

Hepatitis A virus (HAV) encodes a single polyprotein which is posttranslationally processed into the functional structural and nonstructural proteins. Only one protease, viral protease 3C, has been implicated in the nine protein scissions. Processing of the capsid protein precursor region generates a unique intermediate, PX (VP1-2A), which accumulates in infected cells and is assumed to serve as precursor to VP1 found in virions, although the details of this reaction have not been determined. Coexpression in transfected cells of a variety of P1 precursor proteins with viral protease 3C demonstrated efficient production of PX, as well as VP0 and VP3; however, no mature VP1 protein was detected. To identify the C-terminal amino acid residue of HAV VP1, we performed peptide sequence analysis by protease-catalyzed [18O]H2O incorporation followed by liquid chromatography ion-trap microspray tandem mass spectrometry of HAV VP1 isolated from purified virions. Two different cell culture-adapted isolates of HAV, strains HM175pE and HM175p35, were used for these analyses. VP1 preparations from both virus isolates contained heterogeneous C termini. The predominant C-terminal amino acid in both virus preparations was VP1-Ser274, which is located N terminal to a methionine residue in VP1-2A. In addition, the analysis of HM175pE recovered smaller amounts of amino acids VP1-Glu273 and VP1-Thr272. In the case of HM175p35, which contains valine at amino acid position VP1-273, VP1-Thr272 was found in addition to VP1-Ser274. The data suggest that HAV 3C is not the protease responsible for generation of the VP1 C terminus. We propose the involvement of host cell protease(s) in the production of HAV VP1.

Interaction of poly(rC) binding protein 2 with the 5' noncoding region of hepatitis A virus RNA and its effects on translation

Utilization of internal ribosome entry segment (IRES) structures in the 5' noncoding region (5'NCR) of picornavirus RNAs for initiation of translation requires a number of host cell factors whose distribution may vary in different cells and whose requirement may vary for different picornaviruses. We have examined the requirement of the cellular protein poly(rC) binding protein 2 (PCBP2) for hepatitis A virus (HAV) RNA translation. PCBP2 has recently been identified as a factor required for translation and replication of poliovirus (PV) RNA. PCBP2 was shown to be present in FRhK-4 cells, which are permissive for growth of HAV, as it is in HeLa cells, which support translation of HAV RNA but which have not been reported to host replication of the virus. Competition RNA mobility shift assays showed that the 5'NCR of HAV RNA competed for binding of PCBP2 with a probe representing stem-loop IV of the PV 5'NCR. The binding site on HAV RNA was mapped to nucleotides 1 to 157, which includes a pyrimidine-rich sequence. HeLa cell extracts that had been depleted of PCBP2 by passage over a PV stem-loop IV RNA affinity column supported only low levels of HAV RNA translation. Translation activity was restored upon addition of recombinant PCBP2 to the depleted extract. Removal of the 5'-terminal 138 nucleotides of the HAV RNA, or removal of the entire IRES, eliminated the dependence of HAV RNA translation on PCBP2.

Coding sequences enhance internal initiation of translation by hepatitis A virus RNA in vitro

Hepatitis A virus (HAV), unlike other picornaviruses, has a slow-growth phenotype in permissive cell lines and in general does not induce host cell cytopathology. Although there are no published reports of productive infection of HeLa cells by HAV, HAV RNA appears to be readily translated in HeLa cells when transcribed by T7 RNA polymerase provided by a recombinant vaccinia virus. The 5' noncoding region of HAV was fused to poliovirus (PV) coding sequences to determine the effect on translation efficiency in HeLa cell extracts in vitro. Conditions were optimized for utilization of the HAV internal ribosome entry segment (IRES). Transcripts from chimeric constructs fused precisely at the initiation codon were translated very poorly. However, chimeric RNAs which included 114 or more nucleotides from the HAV capsid coding sequences downstream of the initiation codon were translated much more efficiently than those lacking these sequences, making HAV-directed translation efficiency similar to that directed by the PV IRES. Sixty-six nucleotides were insufficient to confer increased translation efficiency. The most 5'-terminal HAV 138 nucleotides, previously determined to be upstream of the IRES, had an inhibitory effect on translation efficiency. Constructs lacking these terminal sequences, or those in which the PV 5'-terminal sequences replaced those from HAV, translated three- to fourfold better than those with the intact HAV 5'-terminal end.

Intact eukaryotic initiation factor 4G is required for hepatitis A virus internal initiation of translation

The requirements for optimal activity of the hepatitis A virus (HAV) internal ribosome entry segment (IRES) differ substantially from those of other picornavirus IRESes. One such difference is that, to date, the HAV IRES is the only one whose efficiency is severely inhibited in the presence of the picornaviral 2A proteinase. Here we describe experiments designed to dissect the mechanism of proteinase-mediated inhibition of HAV translation. Using dicistronic mRNAs translated in vitro, we show that the HAV IRES is inhibited by the foot-and-mouth disease virus Lb proteinase, as well as by the human rhinovirus 2A proteinase. Furthermore, using mutant Lb proteinase, we demonstrate that proteolytic activity is required for inhibition of HAV IRES activity. Translation inhibition correlated closely with the extent of cleavage of the one identified common cellular target for the 2A and Lb proteinases, eukaryotic initiation factor (eIF) 4G, a component of the eIF4F cap-binding protein complex. Total rescue of HAV IRES activity was possible if purified eIF4F was added to translation extracts. In contrast, if the added eIF4F contained cleaved eIF4G, no rescue of HAV IRES activity was evidenced. Thus the HAV IRES requires intact eIF4G for activity. This is unique among the picornavirus IRESes studied to date and may help explain why HAV does not inhibit host cell translation during viral infection.

Comparison of picornaviral IRES-driven internal initiation of translation in cultured cells of different origins

We recently compared the efficiency of six picornaviral internal ribosome entry segments (IRESes) and the hepatitis C virus (HCV) IRES for their ability to drive internal initiation of translationin vitro. Here we present the results of a similar comparison performed in six different cultured cell lines infected with a recombinant vaccinia virus expressing the T7 polymerase and transfected with dicistronic plasmids. The IRESes could be divided into three groups: (i) the cardiovirus and aphthovirus IRESes (and the HCV element) direct internal initiation efficiently in all cell lines tested; (ii) the enterovirus and rhinovirus IRESes are at least equally efficient in several cell lines, but are extremely inefficient in certain cell types; and (iii) the hepatitis A virus IRES is incapable of directing efficient internal initiation in any of the cell lines used (including human hepatocytes). These are the same three groups found when IRESes were classified according to their activitiesin vitro, or according to sequence homologies. In a mouse neuronal cell line, the poliovirus and other type I IRESes were not functional in an artificial bicistronic context. However, infectious poliovirions were produced efficiently after transfection of these cells with a genomic length RNA. Furthermore, activity of the type I IRESes was dramatically increased upon co-expression of the poliovirus 2A proteinase, demonstrating that while IRES efficiency may vary considerably from one cell type to another, at least in some cases viral proteins are capable of overcoming cell-specific translational defects.

Replication of hepatitis A viruses with chimeric 5' nontranslated regions

The role of the 5' nontranslated region in the replication of hepatitis A virus (HAV) was studied by analyzing the translation and replication of chimeric RNAs containing the encephalomyocarditis virus (EMCV) internal ribosome entry segment (IRES) and various lengths (237, 151, or 98 nucleotides [nt]) of the 5'-terminal HAV sequence. Translation of all chimeric RNAs, truncated to encode only capsid protein sequences, occurred with equal efficiency in rabbit reticulocyte lysates and was much enhanced over that exhibited by the HAV IRES. Transfection of FRhK-4 cells with the parental HAV RNA and with chimeric RNA generated a viable virus which was stable over continuous passage; however, more than 151 nt from the 5' terminus of HAV were required to support virus replication. Single-step growth curves of the recovered viruses from the parental RNA transfection and from transfection of RNA containing the EMCV IRES downstream of the first 237 nt of HAV demonstrated replication with similar kinetics and similar yields. When FRhK-4 cells infected with recombinant vaccinia virus producing SP6 RNA polymerase to amplify HAV RNA were transfected with plasmids coding for these viral RNAs or with subclones containing only HAV capsid coding sequences downstream of the parental or chimeric 5' nontranslated region, viral capsid antigens were synthesized from the HAV IRES with an efficiency equal to or greater than that achieved with the EMCV IRES. These data suggest that the inherent translation efficiency of the HAV IRES may not be the major limiting determinant of the slow-growth phenotype of HAV.

Picornavirus internal ribosome entry segments: comparison of translation efficiency and the requirements for optimal internal initiation of translation in vitro

On the basis of primary sequence comparisons and secondary structure predictions, picornavirus internal ribosome entry segments (IRESes) have been divided into three groups (entero- and rhinoviruses; cardio- and and aphthoviruses; and hepatitis A virus). Here, we describe a detailed comparison of the ability of IRESes from each group to direct internal initiation of translation in vitro using a single dicistronic mRNA (the only variable being the IRES inserted into the dicistronic region). We studied the influence of various parameters on the capacity of six different picornaviral IRESes, and the non-picornaviral hepatitis C virus IRES, to direct internal initiation of translation: salt concentration, the addition of HeLa cell proteins to rabbit reticulocyte lysate translation reactions, the presence of foot-and-mouth disease virus Lb or human rhinovirus 2A proteinase. On the basis of the characteristics of IRES-driven translation in vitro, the picornaviral IRESes can be classified in a similar manner to when sequence homologies are considered. IRESes from each of the three groups responded differently to all of the parameters tested, indicating that while all of these elements can direct internal ribosome entry, the functional requirements for efficient IRES activity vary dramatically. In the individual optimal conditions for translation initiation, the best IRESes were those from the cardio- and aphthoviruses, followed by those from the enteroviruses, which exhibited up to 70% of the efficiency of the EMCV element in directing internal initiation of translation.

Cleavage specificity of purified recombinant hepatitis A virus 3C proteinase on natural substrates

Hepatitis A virus (HAV) 3C proteinase expressed in Escherichia coli was purified to homogeneity, and its cleavage specificity towards various parts of the viral polyprotein was analyzed. Intermolecular cleavage of the P2-P3 domain of the HAV polyprotein gave rise to proteins 2A, 2B, 2C, 3ABC, and 3D, suggesting that in addition to the primary cleavage site, all secondary sites within P2 as well as the 3C/3D junction are cleaved by 3C. 3C-mediated processing of the P1-P2 precursor liberated 2A and 2BC, in addition to the structural proteins VP0, VP3, and VP1-2A and the respective intermediate products. A clear dependence on proteinase concentration was found for most cleavage sites, possibly reflecting the cleavage site preference of 3C. The most efficient cleavage occurred at the 2A/2B and 2C/3A junctions. The electrophoretic mobility of processing product 2B, as well as cleavage of the synthetic peptide KGLFSQ*AKISLFYT, suggests that the 2A/2B junction is located at amino acid position 836/837 of the HAV polyprotein. Furthermore, using suitable substrates we obtained evidence that sites VP3/VP1 and VP1/2A are alternatively processed by 3C, leading to either VP1-2A or to P1 and 2A. The results with regard to intermolecular cleavage by purified 3C were confirmed by the product pattern derived from cell-free expression and intramolecular processing of the entire polyprotein. We therefore propose that polyprotein processing of HAV relies on 3C as the single proteinase, possibly assisted by as-yet-undetermined viral or host cell factors and presumably controlled in a concentration-dependent fashion.

Analysis of hepatitis A virus translation in a T7 polymerase-expressing cell line

Hepatitis A virus (HAV) exhibits several characteristics which distinguish it from other picornaviruses, including slow growth in cell culture even after adaptation, and lack of host-cell protein synthesis shut-down. Like other picornaviruses, HAV contains a long 5' nontranslated region (NTR) incorporating an internal ribosomal entry site (IRES), which directs cap-independent translation. We compared HAV IRES-initiated translation with translation initiated by the structurally similar encephalomyocarditis virus (EMCV) IRES, using plasmids in which each of the 5'NTRs is linked in-frame with the chloramphenicol acetyltransferase (CAT) gene. Translation was assessed in an HAV-permissive cell line which constitutively expresses T7 RNA polymerase and transcribes high levels of uncapped RNA from these plasmids following transfection. RNAs containing the EMCV IRES were efficiently translated in these cells, while those containing the HAV IRES were translated very poorly. Analysis of translation of these RNAs in the presence of poliovirus protein 2A, which shuts down cap-dependent translation, demonstrated that their translation was cap independent. Our results suggest that the HAV IRES may function poorly in these cells, and that inefficient translation may contribute to the exceptionally slow replication cycle characteristic of cell culture-adapted HAV.

Internal initiation of translation

Although the 5' cap-dependent scanning mechanism can account for the translational initiation of most mRNAs in eukaryotic cells, several viral and cellular mRNAs contain nucleotide sequences in their 5' non-coding regions that can mediate binding of ribosomes to the mRNA, regardless of the modification state of the 5' ends. During the past year, some nuclear proteins normally involved in RNA processing have been shown also to facilitate 'internal' ribosome binding. Unexpected dual functions have, therefore, been suggested for these RNA-binding proteins, in both RNA biogenesis in the nucleus and RNA translation in the cytoplasm.

Intermolecular cleavage of hepatitis A virus (HAV) precursor protein P1-P2 by recombinant HAV proteinase 3C

Active proteinase 3C of hepatitis A virus (HAV) was expressed in bacteria either as a mature enzyme or as a protein fused to the entire polymerase 3D or to a part of it, and their identities were shown by immunoblot analysis. Intermolecular cleavage activity was demonstrated by incubating in vitro-translated and radiolabeled HAV precursor protein P1-P2 with extracts of bacteria transformed with plasmids containing recombinant HAV 3C. Identification of cleavage products P1, VP1, and VPO-VP3 by immunoprecipitation clearly demonstrates that HAV 3C can cleave between P1 and P2 as well as within P1 and thus shows an activity profile similar to that of cardiovirus 3C.

A cis-acting element within the hepatitis A virus 5'-non-coding region required for in vitro translation

Every picornavirus studied thus far has a sequence within the 5'-non-coding region that is required for internal ribosome binding and translation of the polyprotein. In an attempt to identify this region in hepatitis A virus we constructed a truncated hepatitis A virus (HAV) cDNA clone that contains the entire 736 bp 5' non-coding region (5'-NCR) and 754 base pairs of the viral capsid coding region (P1) under control of the SP6 promoter. In vitro transcription and translation of this transcript in a rabbit reticulocyte lysate yielded a protein product of about 29 kDa as analyzed by autoradiography following sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE). A series of mutations of this construct have defined a minimal sequence between bases 347 and 734 in the 5'-NCR that is required for efficient in vitro translation. The deleted constructs (D 523-734 and D 632-734) showed a reduced ability to translate in the rabbit reticulocyte lysate system in comparison with the full-length 5'-NCR construct, pH1489. The translation of these deleted constructs was artificially restored by the addition of a 5'-terminal methylated cap structure, m7GpppG, to the RNA. This increase in translational efficiency could be competed away with cap analog (m7GDP) thus indicating that this region is required for cap-independent internal ribosome binding for HAV translation.

Polyprotein processing in cis and in trans by hepatitis A virus 3C protease cloned and expressed in Escherichia coli

To determine the P3 region protein-processing sites cleaved by the hepatitis A virus 3C protease, a nested set of constructs containing a portion of 3A (3A* [the asterisk denotes an incomplete protein]), 3B and 3C and various amounts of 3D, fused in frame to Escherichia coli TrpE-coding sequences under control of the tryptophan promoter, was made. Additional plasmids that encoded a portion of 2C (2C*) and the P3 proteins, including complete or incomplete 3D sequences, were constructed. After induction, E. coli containing these recombinant plasmids produced high levels of fusion proteins as insoluble aggregates. 3C-mediated cleavage products were identified by comparison of expression with a matching set of plasmids, containing an engineered mutation in 3C. Cleavage products were detected by immunoblot analyses by using antisera against the TrpE protein, against 3D*, and against 3CD*. Scissile bonds were determined by N-terminal amino acid sequencing of the proteins formed by cleavage. The results showed that when a portion of 2C was present, the primary cleavage by the 3C protease was between 2C and 3A, and the cleavage site was QG, as predicted by J. I. Cohen, J. R. Ticehurst, R. H. Purcell, A. Buckler-White, and B. M. Baroudy, J. Virol. 61:50-59, 1987. Very little further cleavage of the released P3 protein was detected. When the fusion protein contained no 2C and included only 3A*-to-3D sequences, efficient cleavage occurred between 3B and 3C, at the QS pair, also as predicted by Cohen et al. (J. Virol. 61:50-59, 1987). The latter proteins were also cleaved between 3C and 3D, but less efficiently than between 3B and 3C. Extracts of bacteria expressing proteins from 3A* to 3D also cleaved a radiolabelled hepatitis A virus substrate containing VP1*2ABC* sequences in trans.

Hepatitis A virus polyprotein synthesis initiates from two alternative AUG codons

The genomic RNA of hepatitis A virus has two potential translation initiation sites for synthesis of a 251-kDa polyprotein. It is not known which of these AUG codons, located at positions 735-737 and 741-743, is used in vitro or in vivo. Site-directed mutagenesis was carried out to eliminate each start codon independently. Transcripts from the unmodified and modified cDNA clones were used either to program an in vitro translation system or for transfection of BS-C-1 cells. In vitro and in vivo translation data revealed preferential usage of the downstream AUG located at position 741 to 743, although either site could be utilized in the absence of the other. Both modified RNAs were able to induce productive infections in BS-C-1 cells. Deletion of almost all of the 5'-untranslated region (5'UTR) of the RNA, however, stimulated selection of AUG 735-737 in vitro resulting in equal utilization of both sites, suggesting a strong influence of the 5'UTR for directing the ribosome to a specific internal initiation site.

Replication of hepatitis A virus and processing of proteins

Isolation and propagation of hepatitis A virus (HAV) in cell culture is routinely possible. All primary HAV isolates and most established virus strains, however, show a protracted replication behaviour and tend to establish a persistent infection. Rapidly replicating, cytolytic variant viruses can be selected from persistently infected cultures under distinct conditions. Factors critical for the outcome of HAV infection include the genetics of the virus, the physiological state of the infected cell, the presence of defective interfering particles, synthesis and encapsidation of viral RNA and possibly synthesis and processing of viral proteins. Analysis of the latter events have proved to be difficult. Only seven of the 11 peptides coded for by the HAV genome have been experimentally identified and the sequence of cleavages by which they are released from the precursor polyprotein is still a matter of discussion.

Detection of hepatitis A virus proteins in infected BS-C-1 cells

Hepatitis A virus (HAV) is distinguished from other picornaviruses by its tropism for the liver in infected hosts, a nonlytic infection in hepatocytes, and a slow and nonlytic growth cycle in cultured cells. Although the genome structure and organization of HAV appear to be similar to those of the other picornaviruses, the viral proteins synthesized in infected cells have not been previously characterized. We have utilized specific antisera raised in rabbits to recombinant HAV proteins expressed in Escherichia coli in an effort to identify both structural and nonstructural proteins in BS-C-1 cells throughout the course of a viral replication cycle. Replication was monitored by dot blot hybridization of viral genomes. Structural proteins VP0, VP1, VP2, and VP3 were found to accumulate during the infection cycle as did viral RNA. Nonstructural proteins 2C and 3D were not detected on immunoblots, although a minor amount of 2C could be detected by immunoprecipitation of lysates of radiolabeled, infected cells. The relative sensitivities of the various antisera were determined, and the failure to observe nonstructural proteins was shown not to be due to decreased sensitivity of the detection reagents. Thus, it appears that HAV nonstructural proteins do not accumulate in infected cells to levels comparable to those of capsid proteins.