Mutations within the 5' nontranslated RNA of cell culture-adapted hepatitis A virus which enhance cap-independent translation in cultured African green monkey kidney cells

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

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.

Association between severity of type A hepatitis and nucleotide variations in the 5' non-translated region of hepatitis A virus RNA: strains from fulminant hepatitis have fewer nucleotide substitutions

BACKGROUND

Type A hepatitis is still a considerable problem in both underdeveloped and developed countries. Why some patients progress to fulminant type A hepatitis and others do not is unclear.

AIMS

To determine if nucleotide differences in the genome of hepatitis A virus (HAV) are responsible for the range of clinical severities, we analysed the 5' non-translated region (5'NTR) of the HAV genome, which has an internal ribosomal entry site and is important for cap independent translation of the viral message.

METHODS

Serum samples from 84 Japanese patients with sporadic type A hepatitis from five distant regions of Japan, comprising 12 patients with fulminant hepatitis (FH), 13 with severe acute hepatitis (AHs), and 59 with acute hepatitis (AH), were examined for HAV RNA. The fragment between nucleotides 75 and 638 of the 5'NTR was amplified by reverse transcription-polymerase chain reaction, and the nucleotide sequence was determined by direct sequencing.

RESULTS

Comparison of sequences of the 5'NTR revealed relatively fewer nucleotide substitutions in FH and AHs patients compared with the considerable sequence variations found in strains of AH. This tendency was most prominent between nucleotides 200 and 500. Strains from FH and AHs cases had fewer nucleotide substitutions (p<0.001) in this region.

CONCLUSIONS

Nucleotide variations in the central portion of the 5'NTR of HAV may influence the severity of type A hepatitis.

Replication of subgenomic hepatitis A virus RNAs expressing firefly luciferase is enhanced by mutations associated with adaptation of virus to growth in cultured cells

Replication of hepatitis A virus (HAV) in cultured cells is inefficient and difficult to study due to its protracted and generally noncytopathic cycle. To gain a better understanding of the mechanisms involved, we constructed a subgenomic HAV replicon by replacing most of the P1 capsid-coding sequence from an infectious cDNA copy of the cell culture-adapted HM175/18f virus genome with sequence encoding firefly luciferase. Replication of this RNA in transfected Huh-7 cells (derived from a human hepatocellular carcinoma) led to increased expression of luciferase relative to that in cells transfected with similar RNA transcripts containing a lethal premature termination mutation in 3D(pol) (RNA polymerase). However, replication could not be confirmed in either FrhK4 cells or BSC-1 cells, cells that are typically used for propagation of HAV. Replication was substantially slower than that observed with replicons derived from other picornaviruses, as the basal luciferase activity produced by translation of input RNA did not begin to increase until 24 to 48 h after transfection. Replication of the RNA was reversibly inhibited by guanidine. The inclusion of VP4 sequence downstream of the viral internal ribosomal entry site had no effect on the basal level of luciferase or subsequent increases in luciferase related to its amplification. Thus, in this system this sequence does not contribute to viral translation or replication, as suggested previously. Amplification of the replicon RNA was profoundly enhanced by the inclusion of P2 (but not 5' noncoding sequence or P3) segment mutations associated with adaptation of wild-type virus to growth in cell culture. These results provide a simple reporter system for monitoring the translation and replication of HAV RNA and show that critical mutations that enhance the growth of virus in cultured cells do so by promoting replication of viral RNA in the absence of encapsidation, packaging, and cellular export of the viral genome.

Analysis of full-length hepatitis A virus genome in sera from patients with fulminant and self-limited acute type A hepatitis

BACKGROUND/AIMS

Type A hepatitis still poses a considerable problem worldwide. Why some patients progress to fulminant type A hepatitis and others do not is still unknown. To examine whether genomic differences of hepatitis A virus (HAV) are responsible for the severity of the disease, we analyzed the whole HAV genomes from patients with fulminant and self-limited acute type A hepatitis.

METHODS

Sera from three patients with sporadic type A fulminant hepatitis (FH) and three patients with acute hepatitis (AH) were examined for HAV RNA. Full-length nucleotide sequences were determined using long reverse transcription polymerase chain reaction, 5' and 3' rapid amplification of cDNA ends methods, and direct sequencing. The amino acid sequences were deduced from the nucleotide sequences.

RESULTS

HAV RNA was detected in all six patients examined. From the sequence of viral protein 1/2A, all cases were revealed to be genotype IA. By comparing with genotype IA, wild-type HAV strain GBM, the analysis of whole genomes from the six cases showed no specific substitutions between FH and AH. Completely identical nucleotide sequences were observed at 3' non-translated region (NTR) in all six cases. In 5'NTR, less nucleotide substitutions were found in FH than in AH, and in the non-structural protein 2B region, a little more amino acid substitutions seemed to be found in FH than in AH.

CONCLUSIONS

This study showed that full-length HAV could be analyzed from serum samples. Although there were no unique nucleotide or amino acid substitutions, possible associations were suggested between the severity of type A hepatitis and the nucleotide substitutions in 5'NTR and the amino acid substitutions in 2B.

Characterization of recombinant hepatitis A virus genomes containing exogenous sequences at the 2A/2B junction

Hepatitis A virus (HAV) differs from other members of the family Picornaviridae in that the cleavage of the polyprotein at the 2A/2B junction, commonly considered to be the primary polyprotein cleavage by analogy with other picornaviruses, is mediated by 3C(pro), the only proteinase encoded by the virus. However, it has never been formally demonstrated that the 2A/2B junction is the site of primary cleavage, and the actual function of the 2A sequence, which lacks homology with sequence of other picornaviruses, remains unknown. To determine whether 2A functions in cis as a precursor with the nonstructural proteins, we constructed dicistronic HAV genomes in which a heterologous picornaviral internal ribosome entry site was inserted at the 2A/2B junction. Transfection of permissive FRhK-4 cells with these dicistronic RNAs failed to result in the rescue of infectious virus, indicating a possible cis replication function spanning the 2A/2B junction. However, infectious virus was recovered from recombinant HAV genomes containing exogenous protein-coding sequences inserted in-frame at the 2A/2B junction and flanked by consensus 3C(pro) cleavage sites. The replication of these recombinants was less efficient than that of the parent virus but was variable and not dependent upon the length of the inserted sequence. An HAV recombinant containing a 420-nt insertion encoding the bleomycin resistance protein Zeo was stable for up to five passages in cell culture. Inserted sequences were deleted from replicating viruses, but this did not result from homologous recombination at the flanking 3C(pro) cleavage sites, since the 5' and 3' segments of the inserted sequence were retained in the deletion mutants. These results indicate that the HAV polyprotein can tolerate an insertion at the 2A/2B junction and that the 2A polypeptide does not function in cis as a 2AB precursor. Recombinant HAV genomes containing foreign protein-coding sequences inserted at the 2A/2B junction are novel and potentially useful protein expression vectors.

PCR-SSCP analysis of 5'-nontranslated region of hepatitis A viral RNA: comparison with clinicopathological features of hepatitis A

The recent development of the sensitive reverse transcription-polymerase chain reaction (RT-PCR) method allowed us to detect the presence of hepatitis A virus (HAV) RNA in sera from hepatitis A patients. To determine whether differences in HAV are related to the wide range of clinical severity, we used PCR-single strand conformation polymorphism (SSCP) to analyze the amplified product of the 5'-nontranslated region (5'NTR), where relatively homologous sequences are reported and the internal ribosomal entry site is considered to exist, from these various levels of hepatitis A. Twenty-seven patients admitted to Chiba University Hospital (between 1988 and 1997) were examined for HAV RNA in their sera by RT-PCR with primers located at 5'NTR of HAV RNA. The nucleotide (nt) sequence of a central part (nt 277-551) of 5'NTR was amplified and the product was examined by PCR-SSCP. HAV RNA was detected in all 27 hepatitis A patients examined: in 3 with fulminant hepatitis, 2 with severe acute hepatitis, and 22 with self-limited acute hepatitits. The amplified sequence revealed by PCR-SSCP showed that samples from fulminant and severe acute hepatitis patients had similar mobility in the gel, whereas that from acute hepatitis patients demonstrated a considerable variety in mobility patterns. From the analysis of the amplified product of 5'NTR of HAV, the bands are likely to be similar in the more severe forms of hepatitis A compared to those from uncomplicated self-limited acute hepatitis.

Cell type-specific enhancement of hepatitis C virus internal ribosome entry site-directed translation due to 5' nontranslated region substitutions selected during passage of virus in lymphoblastoid cells

Low-level replication of hepatitis C virus (HCV) in cultured lymphoblastoid cells inoculated with H77 serum inoculum led to the appearance of new virus variants containing identical substitutions at three sites within the viral 5' nontranslated RNA (5'NTR): G(107)-->A, C(204)-->A, and G(243)-->A (N. Nakajima, M. Hijikata, H. Yoshikura, and Y. K. Shimizu, J. Virol. 70:3325-3329, 1996). These results suggest that virus with this 5'NTR sequence may have a greater capacity for replication in such cells, possibly due to more efficient cap-independent translation, since these nucleotide substitutions reside within the viral internal ribosome entry site (IRES). To test this hypothesis, we examined the translation of dicistronic RNAs containing upstream and downstream reporter sequences (Renilla and firefly luciferases, respectively) separated by IRES sequences containing different combinations of these substitutions. The activity of the IRES was assessed by determining the relative firefly and Renilla luciferase activities expressed in transfected cells. Compared with the IRES present in the dominant H77 quasispecies, an IRES containing all three nucleotide substitutions had significantly greater translational activity in three of five human lymphoblastoid cell lines (Raji, Bjab, and Molt4 but not Jurkat or HPBMa10-2 cells). In contrast, these substitutions did not enhance IRES activity in cell lines derived from monocytes or granulocytes (HL-60, KG-1, or THP-1) or hepatocytes (Huh-7) or in cell-free translation assays carried out with rabbit reticulocyte lysates. Each of the three substitutions was required for maximally increased translational activity in the lymphoblastoid cells. The 2- to 2.5-fold increase in translation observed with the modified IRES sequence may facilitate the replication of HCV, possibly accounting for differences in quasispecies variants recovered from liver tissue and peripheral blood mononuclear cells of the same patient.

Functional significance of the interaction of hepatitis A virus RNA with glyceraldehyde 3-phosphate dehydrogenase (GAPDH): opposing effects of GAPDH and polypyrimidine tract binding protein on internal ribosome entry site function

Glyceraldehyde 3-phosphate dehydrogenase (GAPDH), a cellular enzyme involved in glycolysis, binds specifically to several viral RNAs, but the functional significance of this interaction is uncertain. Both GAPDH and polypyrimidine tract binding protein (PTB) bind to overlapping sites in stem-loop IIIa of the internal ribosome entry site (IRES) of Hepatitis A virus (HAV), a picornavirus. Since the binding of GAPDH destabilizes the RNA secondary structure, we reasoned that GAPDH may suppress the ability of the IRES to direct cap-independent translation, making its effects antagonistic to the translation-enhancing activity of PTB (D. E. Schultz, C. C. Hardin, and S. M. Lemon, J. Biol. Chem. 271:14134-14142, 1996). To test this hypothesis, we constructed plasmids containing a dicistronic transcriptional unit in which the HAV IRES was placed between an upstream GAPDH-coding sequence and a downstream Renilla luciferase (RLuc) sequence. Transfection with this plasmid results in overexpression of GAPDH and in RLuc production as a measure of IRES activity. RLuc activity was compared with that from a control, null-expression plasmid that was identical except for a frameshift mutation within the 5' GAPDH coding sequence. In transfection experiments, GAPDH overexpression significantly suppressed HAV IRES activity in BSC-1 and FRhK-4 cells but not in Huh-7 cells, which have a significantly greater cytoplasmic abundance of PTB. GAPDH suppression of HAV translation was greater with the wild-type HAV IRES than with the IRES from a cell culture-adapted virus (HM175/P16) that has reproducibly higher basal translational activity in BSC-1 cells. Stem-loop IIIa RNA from the latter IRES had significantly lower affinity for GAPDH in filter binding experiments. Thus, the binding of GAPDH to the IRES of HAV suppresses cap-independent viral translation in vivo in African green monkey kidney cells. The enhanced replication capacity of cell culture-adapted HAV in such cells may be due in part to reduced affinity of the viral IRES for GAPDH.

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.

Transient expression of cellular polypyrimidine-tract binding protein stimulates cap-independent translation directed by both picornaviral and flaviviral internal ribosome entry sites In vivo

The regulation of cap-independent translation directed by the internal ribosome entry sites (IRESs) present in some viral and cellular RNAs is poorly understood. Polypyrimidine-tract binding protein (PTB) binds specifically to several viral IRESs. IRES-directed translation may be reduced in cell-free systems that are depleted of PTB and restored by reconstitution of lysates with recombinant PTB. However, there are no data concerning the effects of PTB on IRES-directed translation in vivo. We transfected cells with plasmids expressing dicistronic transcripts in which the upstream cistron encoded PTB or PTB deletion mutants (including a null mutant lacking amino acid residues 87 to 531). The downstream cistron encoded a reporter protein (chloramphenicol acetyltransferase [CAT]) under translational control of the poliovirus IRES which was placed within the intercistronic space. In transfected BS-C-1 cells, transcripts expressing wild-type PTB produced 12-fold more reporter protein than similar transcripts encoding the PTB null mutant. There was a 2.4-fold difference in CAT produced from these transcripts in HeLa cells, which contain a greater natural abundance of PTB. PTB similarly stimulated CAT production from transcripts containing the IRES of hepatitis A virus or hepatitis C virus in BS-C-1 cells and Huh-7 cells (37- to 44-fold increase and 5 to 5.3-fold increase, respectively). Since PTB had no quantitative or qualitative effect on transcription from these plasmids, we conclude that PTB stimulates translation of representative picornaviral and flaviviral RNAs in vivo. This is likely to reflect the stabilization of higher ordered RNA structures within the IRES and was not observed with PTB mutants lacking RNA recognition motifs located in the C-terminal third of the molecule.

Internal ribosome entry sites (IRESs): reality and use

IRESs are known to recruit ribosomes directly, without a previous scanning of untranslated region of mRNA by the ribosomes. IRESs have been found in a number of viral and cellular mRNAs. Experimentally, IRESs are commonly used to direct the expression of the second cistrons of bicistronic mRNAs. The mechanism of action of IRESs is not fully understood and a certain number of laboratories were not successful in using them in a reliable manner. Three observations done in our laboratory suggested that IRESs might not work as functionally as it was generally believed. Stem loops added before IRESs inhibited mRNA translation. When added into bicistronic mRNAs, IRESs initiated translation of the second cistrons efficiently only when the intercistronic region contained about 80 nucleotides, and they did not work any more effectively with intercistronic regions containing at least 300-400 nucleotides. Conversely, IRESs inserted at any position into the coding region of a cistron interrupted its translation and initiated translation of the following cistron. The first two data are hardly compatible with the idea that IRESs are able to recruit ribosomes without using the classical scanning mechanism. IRESs are highly structured and cannot be scanned by the 40S ribosomal subunit. We suggest that IRESs are short-circuited and are essentially potent stimulators favoring translation in particular physiological situations.

Natural variation in translational activities of the 5' nontranslated RNAs of hepatitis C virus genotypes 1a and 1b: evidence for a long-range RNA-RNA interaction outside of the internal ribosomal entry site

The 5' nontranslated RNA (5'NTR) of a genotype 1b hepatitis C virus (HCV-N) directs cap-independent translation of the HCV-N polyprotein with about twofold less efficiency than the 5'NTR of a genotype 1a virus under physiologic conditions (Hutchinson strain, or HCV-H) (M. Honda et al., Virology 222:31-42, 1996). Here, we show by mutational analysis that substitution of the AG dinucleotide sequence at nucleotides (nt) 34 and 35 of HCV-N with GA (present in HCV-H) restores the translational activity to that of the HCV-H 5'NTR both in vitro and in vivo. These nucleotides are located upstream of the minimal essential internal ribosome entry site (IRES), as a 6-nt deletion spanning nt 32 to 37 also increased the translational activity of the HCV-N 5'NTR to that of HCV-H. Thus, the upstream AG dinucleotide sequence has an inhibitory effect on IRES-directed translation. Surprisingly, however, this inhibitory effect was observed only when the translated, downstream RNA sequence contained nt 408 to 929 of HCV (capsid-coding RNA). Further analysis of RNA transcripts containing frameshift mutations demonstrated that the nucleotide sequence of the transcript, and not the amino acid sequence of the expressed capsid protein, determines this difference in translation efficiency. The difference between the translational activities of the HCV-N and HCV-H transcripts was increased when translation was carried out in reticulocyte lysates containing high K+ concentrations, with a sevenfold difference evident at 130 to 150 mM K+. These results suggest that there is an RNA-RNA interaction involving 5'NTR and capsid-coding sequences flanking the IRES and that this is responsible for the reduced IRES activity of the genotype 1b virus, HCV-N.

A phylogenetically conserved stem-loop structure at the 5' border of the internal ribosome entry site of hepatitis C virus is required for cap-independent viral translation

Hepatitis C virus (HCV) initiates translation of its polyprotein under the control of an internal ribosome entry site (IRES) that comprises most of the 341-nucleotide (nt) 5' nontranslated RNA (5'NTR). A comparative analysis of related flaviviral sequences suggested that an RNA segment for which secondary structure was previously ill defined (domain II, nt 44 to 118) forms a conserved stem-loop that is located at the 5' border of the HCV IRES and thus may function in viral translation. This prediction was tested by a mutational analysis of putative helical structures that examined the impact of both covariant and noncovariant nucleotide substitutions on IRES activity in vivo and in vitro. Results of these experiments provide support for predicted base pair interactions between nt 44 to 52 and 111 to 118 and between nt 65 to 70 and 97 to 102 of the HCV 5'NTR. Substitutions at either nt 45 and 46 or nt 116 and 117 resulted in reciprocal changes in V1 nuclease cleavage patterns within the opposing strand of the putative helix, consistent with the predicted base pair interactions. IRES activity was highly dependent on maintenance of the stem-loop II structure but relatively tolerant of covariant nucleotide substitutions within predicted helical segments. Sequence alignments suggested that the deduced domain II structure is conserved within the IRESs of pestiviruses as well as the novel flavivirus GB virus B. Despite marked differences in primary nucleotide sequence within conserved helical segments, the sequences of the intervening single-stranded loop segments are highly conserved in these different viruses. This suggests that these segments of the viral RNA may interact with elements of the host translational machinery that are broadly conserved among different mammalian species.

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.

Efficient long-term coexpression of a hammerhead ribozyme targeted to the U5 region of HIV-1 LTR by linkage to the multidrug-resistance gene

Ribozymes as anti-HIV-1 agents hold promise for the treatment of AIDS. They can be delivered into cells either exogenously or through an expression system. For effective protection against HIV-1, sufficient and sustained amounts of the antiviral ribozymes must be delivered into target cells. The coexpression of a dominant selectable marker with ribozymes would serve to enrich for cells containing the molecular antiviral and facilitate prolonged expression of these ribozymes. The multidrug resistance gene (MDR1) is a potential clinically relevant selectable marker and offers many advantages over other known dominant selectable markers, including the use of diverse pharmacologically characterized drug or drug combinations for selection. Harvey sarcoma-based retroviral vectors encoding the MDR1 multidrug transporter with a hammerhead ribozyme targeted to highly conserved sequences within the HIV-1 U5 LTR segment have been constructed in a bicistronic format. The internal ribosome entry site (IRES) from encephalomyocarditis virus was used to initiate translation of the MDR1 mRNA. The ribozyme remained functional despite being tethered to MDR1. Long-term, high-level expression of both the ribozyme and MDR1, as evident by RT-PCR and FACS analysis, was observed in a human T cell line containing the construct selected with vincristine, a cytotoxic substrate for the multidrug transporter.

Interaction of hepatitis A virus (HAV) precursor proteins 3AB and 3ABC with the 5' and 3' termini of the HAV RNA

RNA secondary structures within the terminal nontranslated regions of entero- and rhinoviral genomes interact specifically with viral nonstructural proteins and are required in cis for viral RNA replication. Here we show that recombinant hepatitis A virus (HAV) polypeptide 3ABC specifically interacts in vitro with secondary RNA structures formed at both the 5' and 3' terminus of the viral genome. Similar to protein 3AB, HAV 3ABC bound to the 3' terminal RNA structure which did not interact with the mature proteinase 3C. In contrast to 3AB, 3ABC interacted with RNA stem-loop IIa and combinations of individual secondary structure elements of the 5' noncoding region. RNA binding of the precursor polypeptide 3ABC was 50 times stronger than that of 3AB and 3C, implicating a specific role of this stable processing intermediate in viral genome replication.

Progress toward the development of a genetically engineered attenuated hepatitis A virus vaccine

Mutations which positively affect growth of hepatitis A virus in cell culture may negatively affect growth in vivo. Therefore, development of an attenuated vaccine for hepatitis A may require a careful balancing of mutations to produce a virus that will grow efficiently in cells suitable for vaccine production and still maintain a satisfactory level of attenuation in vivo. Since such a balance could be achieved most directly by genetic engineering, we are analyzing mutations that accumulated during serial passage of the HM-175 strain of hepatitis A virus in MRC-5 cell cultures in order to determine the relative importance of the mutations for growth in MRC-5 cells and for attenuation in susceptible primates. Chimeric viral genomes of the HM-175 strain were constructed from cDNA clones derived from a virulent virus and from two attenuated viruses adapted to growth in African green monkey kidney (AGMK) and MRC-5 cells, respectively. Viruses encoded by these chimeric genomes were recovered by in vitro or in vivo transfection and assessed for their ability to grow in cultured MRC-5 cells or to cause hepatitis in primates (tamarins). The only MRC-5-specific mutations that substantially increased the efficiency of growth in MRC-5 cells were a group of four mutations in the 5' noncoding (NC) region. These 5' NC mutations and a separate group of 5' NC mutations that accumulated during earlier passages of the HM-175 virus in primary AGMK cells appeared, independently and additively, to result in decreased biochemical evidence of hepatitis in tamarins. However, neither group of 5' NC mutations had a demonstrable effect on the extent of virus excretion or liver pathology in these animals.

Translation initiation in GB viruses A and C: evidence for internal ribosome entry and implications for genome organization

GB viruses A and C (GBV-A and GBV-C) are two recently described RNA viruses which appear to be members of the Flaviviridae. Although both viruses appear to contain long 5' nontranslated regions, the sites of polyprotein initiation and the presence of core-like proteins remain to be determined. Translation studies were undertaken to determine the mechanism and sites of polyprotein initiation in GBV-A and GBV-C. Rabbit reticulocyte lysates programmed with monocistronic RNAs containing 5' ends of GBV-A or GBV-C fused in-frame with the chloramphenicol acetyltransferase (CAT) open reading frame generated GBV-CAT fusion proteins in vitro. Site-specific mutagenesis and N-terminal sequencing located the sites of translation initiation immediately upstream of the putative signal sequence for the GBV E1 envelope glycoproteins. Efficient translation of the monocistronic GBV-CAT RNAs required the inclusion of GBV coding sequences. This, coupled with the presence of at least 523 nucleotides of 5' nontranslated RNA containing multiple AUG codons, suggests that translation initiation of these RNAs did not utilize a ribosome scanning mechanism. Translation of bicistronic RNAs containing 5' nontranslated sequences within the intercistronic space was consistent with the presence of a weakly active internal ribosome entry site in both GBV-A and GBV-C. Secondary structure predictions indicate that the 5' ends of these viruses assume similar complex structures distinct from those identified in the internal ribosome entry site-containing picornaviruses, pestiviruses, and hepatitis C viruses. The data indicate that GBV-A and GBV-C are unique members of the Flaviviridae that do not contain core-like proteins at the N termini of their putative polyproteins.

Specific interaction of glyceraldehyde 3-phosphate dehydrogenase with the 5'-nontranslated RNA of hepatitis A virus

Initiation of translation of hepatitis A virus (HAV) RNA occurs by internal entry and is likely to involve the interaction of trans-acting cellular protein factors with cis-acting structural elements of an internal ribosomal entry segment (IRES) within the 5'-nontranslated RNA. To characterize interactions between African green monkey kidney (BS-C-1) cell proteins and the predicted stem-loop IIIa (nucleotides 155-235) located at the 5' border of the HAV IRES, we utilized an electrophoresis mobility shift assay (EMSA) to identify a 39-kDa RNA-binding protein (p39). Amino-terminal amino acid sequencing of highly purified p39 revealed absolute identity with human glyceraldehyde 3-phosphate dehydrogenase (GAPDH). The identity of p39 as simian GAPDH was further confirmed by antigenic and biochemical similarities between p39 and human GAPDH. Analysis of the RNA binding properties of simian GAPDH revealed that this cellular protein interacts with two additional sites in the HAV 5'-nontranslated RNA, one located between nucleotides 1-148 and the other between nucleotides 597-746. Competitive EMSAs also demonstrated that GAPDH and human polypyrimidine tract-binding protein, a putative picornavirus translation initiation factor, compete with each other for binding to stem-loop IIIa, suggesting that the relative cytoplasmic abundance of GAPDH and polypyrimidine tract-binding protein in individual cell-types may be an important determinant of viral translation activity. Human GAPDH was found to destabilize the folded structure of the stem-loop IIIa RNA based upon observed decreases in the circular dichroism spectra of this RNA following binding of the protein. This RNA helix-destabilizing activity of GAPDH could directly influence IRES-dependent translation and/or replication of picornavirus RNA.