A new G-tailing method for the determination of the poly(A) tail length applied to hepatitis A virus RNA.

To study the role of the poly(A) tail length during the replication of poly(A)-containing plus-strand RNA virus, we have developed a simple reverse transcription polymerase chain reaction (RT-PCR)-based method that substantially improves the previously reported PAT [poly(A) test] assay. In contrast to the PAT assay, the new method is based on the enzymatic 3' elongation of mRNA with guanosine residues, thus immediately preserving the 3' end of the RNA and creating a unique poly(A)-oligo(G) junction. The oligo(G)-protected full-length poly(A) tail is reverse transcribed using the universal anti-sense primer oligo(dC(9)T(6)) and amplified by PCR with a gene-specific sense primer. After sequencing the resulting RT-PCR product the length of the poly(A) tail was unequivocally deduced from the number of adenosine residues between the oligo(G) stretch and the sequence upstream of the poly(A) tail. The efficiency and specificity of the newly developed assay was demonstrated by analysing the poly(A) tail length of the hepatitis A virus (HAV) RNA. We show here that the poly(A) tail of HAV RNA rescued after transfection of in vitro transcripts was elongated in the course of HAV replication.

Mapping of protein domains of hepatitis A virus 3AB essential for interaction with 3CD and viral RNA.

The small hydrophobic protein 3AB of the picornaviruses, encompassing the replication primer 3B, has been suggested to anchor the viral replication complex to membranes. For hepatitis A virus (HAV) 3AB, we have previously demonstrated its ability to form stable homodimers, to bind to membranes, and to interact specifically with RNA, implicating its multiple involvement in viral replication. In the present report, we show that HAV 3AB additionally interacts with HAV protein 3CD, a feature also described for the corresponding polypeptide of poliovirus. By assessing the interactions of three deletion mutants, distinct domains of HAV 3AB were mapped. The hydrophobic domain and the 3B moiety were found to be essential for the 3AB interaction with 3CD. Both electrostatic and hydrophobic forces are involved in this interaction. The cluster of charged amino acid residues at the C terminus of 3A seems to determine the specificity of 3AB interaction with RNA structures formed at either terminus of the HAV genome. Furthermore, our data implicate that 3A can interact with HAV RNA. Compared with poliovirus 3AB, which by itself is a nonspecific RNA-binding protein, HAV 3AB specifically recognizes HAV RNA structures that might be of relevance for initiation of viral RNA replication.

Improving proteolytic cleavage at the 3A/3B site of the hepatitis A virus polyprotein impairs processing and particle formation, and the impairment can be complemented in trans by 3AB and 3ABC.

The orchestrated liberation of viral proteins by 3C(pro)-mediated proteolysis is pivotal for gene expression by picornaviruses. Proteolytic processing is regulated either by the amino acid sequence at the cleavage site of the substrate or by cofactors covalently or noncovalently linked to the viral proteinase. To determine the role of the amino acid sequence at cleavage sites 3A/3B and 3B/3C that are essential for the liberation of 3C(pro) from its precursors and to assess the function of the stable processing intermediates 3AB and 3ABC, we studied the effect of cleavage site mutations on hepatitis A virus (HAV) polyprotein processing, particle formation, and replication. Using the recombinant vaccinia virus system, we showed that the normally retarded cleavage at the 3A/3B junction can be improved by altering the amino acid sequence at the scissile bond such that it matches the preferred HAV 3C cleavage sites. In contrast to the processing products of the wild-type polyprotein, 3ABC was no longer detectable in the mutant. VP0 and VP3 were generated less efficiently, implying that processing of the structural protein precursor P1-2A depends on the presence of stable 3ABC and/or 3AB. In addition, cleavage of 2BC was impaired in 3AB/3ABC-deficient mutants. Formation of HAV particles was not affected in mutants with blocked 3A/3B and/or 3B/3C cleavage sites. However, 3ABC-deficient mutants produced small numbers of HAV particles, which could be augmented by coexpressing 3AB or 3ABC. The hydrophobic domain of 3A that has been proposed to mediate membrane anchorage of the replication complex was crucial for restoration of defective particle formation. In vitro transcripts of the various cleavage site mutants were unable to initiate an infectious cycle, and no progeny viruses were obtained even after blind passages. Taken together, the data suggest that accumulation of uncleaved HAV 3AB and/or 3ABC is pivotal for both viral replication and efficient particle formation.

Membrane association and RNA binding of recombinant hepatitis A virus protein 2C.

The direct function of hepatitis A virus (HAV) protein 2C, a putative NTPase, is not known, yet genetic evidence obtained from chimeric viruses carrying the 2C genomic region of different HAV variants indicates that it plays a pivotal role in viral replication. In a first assessment of its potential function(s), membrane and RNA binding properties of HAV 2C were studied after expressing the protein in various recombinant systems. In contrast to poliovirus 2C, expression of HAV 2C was inhibitory to the growth and protein synthesis of bacteria. Deletion of the N-terminal amphipathic helix of 2C abrogated this effect and the ability of 2C to associate with eukaryotic membranes. Both, purified 2C and the N-terminally truncated protein were shown to bind RNA in vitro. Our data taken together suggest that HAV 2C is a multifunctional protein.

In vitro RNA binding of the hepatitis A virus proteinase 3C (HAV 3Cpro) to secondary structure elements within the 5' terminus of the HAV genome.

The secondary structure elements at the 5' nontranslated region (NTR) of the picornaviral RNAs can be divided functionally into two domains, one of which directs cap-independent translation, whereas the other is essential for viral RNA replication. For the latter, the formation of an RNA replication complex that involves particularly viral proteinase-containing polypeptides and cellular proteins has been shown (Andino R, Rieckhof GE, Achacoso PL, Baltimore D, 1993, EMBO J 12:3587-3598; Xiang W et al., 1995, RNA 1:892-904). To initiate studies on the formation of the hepatitis A virus (HAV) RNA replication complex, binding of the HAV proteinase 3Cpro and 3CD to secondary structure elements at the 5' and 3' NTR of the HAV RNA was investigated. Using mobility shift assay, UV crosslinking/ label transfer, and northwestern analysis, we show that both the HAV 3Cpro and the proteolytically inactive mutant bind to in vitro synthesized transcripts, suggesting that the RNA-binding site of the enzyme is separated spatially from its catalytic center. Weak interactions with HAV 3Cpro were found for individual secondary structure elements comprising less than 100 nt. RNA-binding specificity was unambiguous for transcripts comprising at least two stem-loops along with the polypyrimidine tract. Furthermore, competition experiments suggest that the 5' terminus of the HAV genome contains multiple binding sites for HAV 3Cpro. In contrast to poliovirus, binding capacity of HAV 3CD to RNA of the 5' NTR was not improved as compared to 3C. The data imply that, during the viral life cycle, HAV 3Cpro might serve replicative function(s) in addition to proteolysis of the viral polyprotein.

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.

RNA-protein interactions at the 3' end of the hepatitis A virus RNA.

The regulative cis-acting terminal RNA structures and the proteins involved in the amplification of the hepatitis A virus (HAV) genome are unknown. By UV cross-linking/label transfer experiments, we have analyzed sequences of the 3'-nontranslated region (3'NTR) and preceding domains of the viral genome for their ability to interact with host proteins. A series of cDNA constructs were used to create genomic- and antigenomic-sense transcripts. The results show that the 3'-NTR-poly(A) interacted with host cell proteins with molecular masses of 38, 45, 57, 84, and 110 kDa only weakly, compared with RNA structures also consisting of 3D-coding regions. Protein p38 was most efficiently labeled after interaction with secondary-structure elements located at the 3' end of the HAV RNA, p38 also interacted with a 5'-terminal RNA probe. Optimal RNA binding was found to be dependent on the salt concentration. The specificity of the RNA-protein interaction was proven by competition assays. These data might indicate that a higher-order structure formed at the junction of the 3Dpol-coding sequence and the 3'-NTR of the HAV genome (putative RNA pseudoknot) significantly improves binding of host proteins and thus suggests that this structure might be essential for the formation of the replication complex initiating minus-strand RNA synthesis.

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.

Proteinase 3C of hepatitis A virus (HAV) cleaves the HAV polyprotein P2-P3 at all sites including VP1/2A and 2A/2B.

Thus far, the only virus-encoded proteinase of hepatitis A virus (HAV) detected is 3C, which was shown to catalyze proteolysis of most of the suggested cleavage sites within the HAV precursor polyprotein. To elucidate whether or not HAV proteinase 3C and its precursors are involved in processing of the yet unidentified sites in the polyprotein P2-P3, the genomic region of 3C including flanking sequences were expressed in a bacterial system and by cell-free translation. In both systems 2A-reactive proteins of 10 (2A) and 16 kDa (delta VP1-2A) were processing products of a polyprotein representing delta VP1-P2-P3* (delta and * denote N- or C-terminally truncated proteins, respectively), thus providing evidence for cleavage at sites VP1/2A and 2A/2B by proteinase 3C. In the cell-free expression system, processing at the P2/P3 junction was rapid and complete, whereas sites 3A/3B, 3B/3C, and 3C/3D were inefficiently cleaved, as evidenced by the accumulation of the stable precursor polypeptides P3* and 3ABC. In contrast to the eukaryotic system, mature 3C was produced in Escherichia coli. Intermolecular cleavage by recombinant 3C occurred at all putative sites within the proteolytically inactive polyprotein P2-P3* mu. The results of this study indicate that proteinase 3C mediates the primary as well as the secondary cleavages of the HAV polyprotein and thus shows an activity profile broader than that of 3C proteinases of other picornaviruses.

Cell-free translation and proteolytic processing of the hepatitis A virus polyprotein.

Virus-encoded proteinase activity of hepatitis A virus (HAV) was studied in vitro. Genomic regions coding for segments of the viral polyprotein were expressed by in vitro transcription and translation in rabbit reticulocyte lysates. Polyproteins translated from synthetic transcripts encoding P1-P2 or delta VP1-P2 were not processed indicating that no proteolytic activity is encoded within P2 of HAV, in contrast to other picornaviruses. Proteinase activity was, however, detected in the genomic region encoding 3C. Mutant transcripts (mu) which encode an alanine in place of the cysteine residue at amino acid position 172 of 3C did not yield proteolytic activity, consistent with the hypothesis that proteinase 3C is a cysteine-containing trypsin-like proteinase. Processing products 3ABC and P3 were identified by immunoprecipitation, providing evidence that proteolytic cleavage occurs at the 2C/3A and less frequently at the 3C/3D junction. For cleavages at either site, the complete 3D moiety was not required. In general, analysis of cleavage products was made difficult by the presence of polypeptides which were translated from internal start sites, predominantly within the P3 region. Since only small amounts of the full-length products P1-P2-P3 or P2-P3 were translated, possible cleavage of P1 and P2 by 3C could not be resolved in this system. Furthermore, no intermolecular cleavage could be detected when in vitro translated polypeptides of the P3 region were incubated with P1, P1-P2 or P2-P3 mu as substrates.

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.

Immunogenicity of inactivated purified tissue culture vaccine against hepatitis A (HepAvac) assessed in laboratory rodents.

Immune response of laboratory rodents (guinea-pigs, CBA and Balb/c mice, Wistar and August rats) to inactivated hepatitis A vaccine was quantitatively assessed. Under comparable conditions of experiment, the mice showed the highest antibody titres and were capable of reacting to the lower doses of immunogen; meanwhile their individual variations in immune response were more pronounced; white rats were the least susceptible to the vaccine, demonstrating the minimal antibody formation; guinea-pigs produced antibody at intermediate levels but the antibody titres were the most homogeneous. The enhancing effect of aluminium hydroxide was observed in guinea-pigs examined at the late postimmunization stage. Differences in immunogenicity of three vaccine lots were essentially similar when these lots were tested as undiluted preparations in guinea-pigs and mice for mean antibody titres and in mice for 50% immune response using serial dilutions of vaccine. All three tests could be routinely employed for vaccine immunogenicity control.

Interaction of uridine diphosphate glucose with calf liver uridine diphosphate glucose dehydrogenase. Significance of hydroxyl groups at C-3, C-4 and C-6 of hexosyl residue.

Analogs of uridine diphosphate glucose (UDPGlc) with a modified hexosyl residue which contained a deoxy-unit at C-3 or C-4 were tested as substrates of calf liver UDPGlc dehydrogenase (EC 1.1.1.22). The 3-deoxyglucose derivative was found not to serve as a substrate for the enzyme whereas the 4-deoxyglucose analog was able to participate in the reaction. The apparent Km of the latter was 5.3 times that of UDPGlc and the relative V was 0.04. The reaction product was identified as uridine diphosphate deoxyhexuronic acid. UDP-deoxyhexoses were non-competitive inhibitors of UDPGlc enzymic oxidation, inhibition increased in the sequence: 2-deoxy-less than 3-and 6-deoxy-less than 4-deoxyglucose derivative. The significance of different HO-groups in hexosyl residue for interaction of UDPGlc with the enzyme is discussed.

Uridine diphosphate 2-deoxyglucose. Chemical synthesis, enzymic oxidation and epimerization.

The paper describes chemical synthesis of uridine diphosphate 2-deocyglucose (UDPdGLc) through reaction of uridine 5'-phosphomorpholidate with 2-deoxy-a-D-glucopyranosyl phosphate. The prepared analog of uridine diphosphate glucose (UDPGlc) served as a substrate for calf liver UDPGlc dehydrogenases (EC 1.1.1.22), the reaction product was identified as nucleotide deoxyhexuronic acid derivative. The apparent Km for UDPdGlc was found to be 60 times that of UDPGlc, and the relative V value for the analog was 0.09. The peculiar lag-eriod in reaction kinetics has been observed for the analog and is presumably connected with the slow rate of the initial stages of the reaction. UDPdGlc was found to be quite an efficient substrate for UDPGlc 4-epimerases (EC 5.13.2) from yeast, calf liver and mung bean seedlings.