Two regions of an avian hepadnavirus RNA pregenome are required in cis for encapsidation.

We have constructed a series of deletion mutants spanning the genome of duck hepatitis B virus in order to determine which regions of the viral genome are required in cis for packaging of the pregenome into capsid particles. Deletion of sequences within either of two nonadjacent regions prevented replication of the mutant viral genomes expressed in a permissive avian hepatoma cell line in the presence of functionally active viral core and P proteins. Extraction of RNA from cells transfected with these replication-defective mutants showed that the mutants retained the capacity to be transcribed into a pregenomic-size viral RNA, but that these RNA species were not packaged into viral capsids. The two regions defined by these deletions are located 36 to 126 (region I) and 1046 to 1214 (region II) nucleotides downstream of the 5' end of the pregenome and contain sequences which are required in cis for encapsidation of the duck hepatitis B virus pregenome.     

Hepadnaviral assembly is initiated by polymerase binding to the encapsidation signal in the viral RNA genome.

Hepadnaviruses, as well as other pararetroviruses, express their pol (P) gene product unfused to the preceding core gene implying that these retroelements have developed a mechanism for initiating assembly and replication that is principally different from the one used by retroviruses and retrotransposons. We have analysed this mechanism for the human hepatitis B virus by using a newly developed, highly sensitive detection method based upon radiolabelling of the P protein at newly introduced target sites for protein kinase A. The results obtained demonstrate that polymerase encapsidation depends on the concomittant encapsidation of the HBV RNA pregenome and that packaging of the viral RNA, in turn, depends on the presence of P protein. Loss of P protein encapsidation by mutations inactivating the HBV RNA encapsidation signal epsilon could be compensated by trans-complementation with recombinant RNA molecules carrying the epsilon sequence. Thus, in contrast to retroviral replication, the interaction of the hepadnaviral P protein and the RNA genome at its packaging signal appears to be crucial for initiating the formation of replication-competent nucleocapsids. Furthermore, RNA control of P protein packaging stringently limits the number of polymerase molecules that can be encapsidated.     

The P gene product of hepatitis B virus is required as a structural component for genomic RNA encapsidation.

Encapsidation of the pregenomic RNA into nucleocapsids is a selective process which depends on specific RNA-protein interactions. The signal involved in the packaging of the hepatitis B virus (HBV) RNA pregenome was recently defined as a short sequence located near the 5' end of that molecule (Junker-Niepmann et al., EMBO J., in press), but it remained an open question which viral proteins are required. Using a genetic approach, we analyzed whether proteins derived from the HBV P gene play an important role in pregenome encapsidation. The results obtained with point mutations, deletions, and insertions scattered throughout the P gene clearly demonstrate that (i) a P gene product containing all functional domains is required both for the encapsidation of HBV pregenomic RNA and for packaging of nonviral RNAs fused to the HBV encapsidation signal, (ii) known enzymatic activities are not involved in the packaging reaction, suggesting that P protein is required as a structural component, and (iii) P protein acts primarily in cis, i.e., pregenomic RNAs from which P protein is synthesized are preferentially encapsidated.     

Mapping the encapsidation determinants of feline immunodeficiency virus

Encapsidation of retroviral RNA involves specific interactions between viral proteins and cis-acting genomic RNA sequences. Human immunodeficiency virus type 1 (HIV-1) RNA encapsidation determinants appear to be more complex and dispersed than those of murine retroviruses. Feline lentiviral (feline immunodeficiency virus [FIV]) encapsidation has not been studied. To gain comparative insight into lentiviral encapsidation and to optimize FIV-based vectors, we used RNase protection assays of cellular and virion RNAs to determine packaging efficiencies of FIV deletion mutants, and we studied replicative phenotypes of mutant viruses. Unlike the case for other mammalian retroviruses, the sequences between the major splice donor (MSD) and the start codon of gag contribute negligibly to FIV encapsidation. Moreover, molecular clones having deletions in this region were replication competent. In contrast, sequences upstream of the MSD were important for encapsidation, and deletion of the U5 element markedly reduced genomic RNA packaging. The contribution of gag sequences to packaging was systematically investigated with subgenomic FIV vectors containing variable portions of the gag open reading frame, with all virion proteins supplied in trans. When no gag sequence was present, packaging was abolished and marker gene transduction was absent. Inclusion of the first 144 nucleotides (nt) of gag increased vector encapsidation to detectable levels, while inclusion of the first 311 nt increased it to nearly wild-type levels and resulted in high-titer FIV vectors. However, the identified proximal gag sequence is necessary but not sufficient, since viral mRNAs that contain all coding regions, with or without as much as 119 nt of adjacent upstream 5' leader, were excluded from encapsidation. The results identify a mechanism whereby FIV can encapsidate its genomic mRNA in preference to subgenomic mRNAs.     

Chimeras of duck and heron hepatitis B viruses provide evidence for functional interactions between viral components of pregenomic RNA encapsidation

Packaging of hepadnavirus pregenomic RNA (pgRNA) into capsids, or encapsidation, requires several viral components. The viral polymerase (P) and the capsid subunit (C) are necessary for pgRNA encapsidation. Previous studies of duck hepatitis B virus (DHBV) indicated that two cis-acting sequences on pgRNA are required for encapsidation: epsilon, which is near the 5' end of pgRNA, and region II, located near the middle of pgRNA. Later studies suggested that the intervening sequence between these two elements may also make a contribution. It has been demonstrated for DHBV that epsilon interacts with P to facilitate encapsidation, but it is not known how other cis-acting sequences contribute to encapsidation. We analyzed chimeras of DHBV and a related virus, heron hepatitis B virus (HHBV), to gain insight into the interactions between the various viral components during pgRNA encapsidation. We learned that having epsilon and P derived from the same virus was not sufficient for high levels of encapsidation, implying that other viral interactions contribute to encapsidation. Chimeric analysis showed that a large sequence containing region II may interact with P and/or C for efficient encapsidation. Further analysis demonstrated that possibly an RNA-RNA interaction between the intervening sequence and region II facilitates pgRNA encapsidation. Together, these results identify functional interactions among various viral components that contribute to pgRNA encapsidation.     

Characterization of the cis-acting contributions to avian hepadnavirus RNA encapsidation

Previous analysis of duck hepatitis B virus (DHBV) indicated the presence of at least two cis-acting sequences required for efficient encapsidation of its pregenomic RNA (pgRNA), epsilon and region II. epsilon, an RNA stem-loop near the 5' end of the pgRNA, has been characterized in detail, while region II, located in the middle of the pgRNA, is not as well defined. Our initial aim was to identify the sequence important for the function of region II in DHBV. We scanned region II and the surrounding sequence by using a quantitative encapsidation assay. We found that the sequence between nucleotides (nt) 438 and 720 contributed to efficient pgRNA encapsidation, while the sequence between nt 538 and 610 made the largest contribution to encapsidation. Additionally, deletions between the two encapsidation sequences, epsilon and region II, had variable effects on encapsidation, while substitutions of heterologous sequence between epsilon and region II disrupted the ability of the pgRNA to be encapsidated efficiently. Overall, these data indicate that the intervening sequences between epsilon and region II play a role in encapsidation. We also analyzed heron hepatitis B virus (HHBV) for the presence of region II and found features similar to DHBV: a broad region necessary for efficient encapsidation that contained a critical region II sequence. Furthermore, we analyzed variants of DHBV that were substituted with HHBV sequence over region II and found that the chimeras were not fully functional for RNA encapsidation. These results indicate that sequences within region II may need to be compatible with other viral components in order to function in pgRNA encapsidation.     

Autogenous regulation of RNA translation and packaging by Rous sarcoma virus Pr76gag.

Unspliced cytoplasmic retroviral RNA in chronically infected cells either is encapsidated by Gag proteins in the manufacture of virus or is used to direct synthesis of Gag proteins. Several models have been suggested to explain the sorting of viral RNA for these two purposes. Here we present evidence supporting a simple biochemical mechanism that accounts for the routing of retroviral RNA. Our results indicate that ribosomes compete with the Gag proteins to determine the fate of nascent retroviral RNA. Although the integrity of the entire Rous sarcoma virus leader sequence is important for retroviral packaging and translation, the RNA structure around the third small open reading frame, which neighbors the psi site required for packaging of the RNA, is particularly critical for maintenance of the balance between translation and packaging. These results support the hypothesis that Gag proteins autogenously regulate their synthesis and encapsidation of retroviral RNA and that an equilibrium exists between RNA destined for translation and packaging that is based on the intracellular levels of Gag proteins and ribosomes. To test the model, mRNAs with natural or mutated 5' leader sequences from Rous sarcoma virus were expressed in avian cells in the presence and absence of Pr76gag. We demonstrate that Pr76gag acts as a translational repressor of these mRNAs in a dose-dependent manner, supporting the hypothesis that Pr76gag can sort retroviral RNA for translation and encapsidation.     

The 17 nucleotides downstream from the env gene stop codon are important for murine leukemia virus packaging

We have identified a previously unknown nucleotide sequence important for the packaging of murine leukemia virus. This nucleotide sequence is located downstream from the stop codon of the env gene but does not overlap the polypurine tract. Deletion of 17 bp from this region resulted in a more than 10-fold decrease in viral titer. Consistent with this result, the deletion mutant showed a 20- to 30-fold drop in the amount of virion RNA in the culture supernatant. The total amount of virion protein in the culture supernatant was comparable for the deletion mutant and the parental virus, suggesting that the mutant construct could release the empty viral particles. These results suggested that the packaging signal sequence might be present at the two extreme sites of the viral genome, one in the region around the splice donor sequence downstream from the 5' long terminal repeat (LTR) and the other immediately upstream from the 3' LTR. Implications for gene therapy, especially in regard to construction of retroviral vectors and packaging constructs, are discussed.     

Evidence for a base-paired region of hepatitis B virus pregenome encapsidation signal which influences the patterns of precore mutations abolishing HBe protein expression.

In two natural HBe-minus hepatitis B virus mutants, expression of HBe protein was abrogated by a nonsense mutation at precore codon 28 and a frameshift mutation at codon 29, respectively. Both mutants contained an additional nucleotide substitution(s) which was found by transfection experiments to be required for efficient packaging of pregenomic RNA. The observed mutational profiles were consistent with the presence of a base-paired region of the pregenome encapsidation signal overlapping the HBe-coding sequence. Results obtained with artificial mutants with significant changes in the primary sequence suggested that base pairing is required but insufficient for efficient pregenome packaging. However, the predicted first four base pairs of the stem are dispensable.     

Avian retroviral RNA encapsidation: reexamination of functional 5' RNA sequences and the role of nucleocapsid Cys-His motifs.

RNA packaging signals (psi) from the 5' ends of murine and avian retroviral genomes have previously been shown to direct encapsidation of heterologous mRNA into the retroviral virion. The avian 5' packaging region has now been further characterized, and we have defined a 270-nucleotide sequence, A psi, which is sufficient to direct packaging of heterologous RNA. Identification of the A psi sequence suggests that several retroviral cis-acting sequences contained in psi+ (the primer binding site, the putative dimer linkage sequence, and the splice donor site) are dispensable for specific RNA encapsidation. Subgenomic env mRNA is not efficiently encapsidated into particles, even though the A psi sequence is present in this RNA. In contrast, spliced heterologous psi-containing RNA is packaged into virions as efficiently as unspliced species; thus splicing per se is not responsible for the failure of env mRNA to be encapsidated. We also found that an avian retroviral mutant deleted for both nucleocapsid Cys-His boxes retains the capacity to encapsidate RNA containing psi sequences, although this RNA is unstable and is thus difficult to detect in mature particles. Electron microscopy reveals that virions produced by this mutant lack a condensed core, which may allow the RNA to be accessible to nucleases.     

The C terminus of foamy retrovirus Gag contains determinants for encapsidation of Pol protein into virions

Foamy viruses (FV) differ from orthoretroviruses in many aspects of their replication cycle. A major difference is in the mode of Pol expression, regulation, and encapsidation into virions. Orthoretroviruses synthesize Pol as a Gag-Pol fusion protein so that Pol is encapsidated into virus particles through Gag assembly domains. However, as FV express Pol independently of Gag from a spliced mRNA, packaging occurs through a distinct mechanism. FV genomic RNA contains cis-acting sequences that are required for Pol packaging, suggesting that Pol binds to RNA for its encapsidation. However, it is not known whether Gag is directly involved in Pol packaging. Previously our laboratory showed that sequences flanking the three glycine-arginine-rich (GR) boxes at the C terminus of FV Gag contain domains important for RNA packaging and Pol expression, cleavage, and packaging. We have now shown that both deletion and substitution mutations in the first GR box (GR1) prevented neither the assembly of particles with wild-type density nor packaging of RNA genomes but led to a defect in Pol packaging. Site-directed mutagenesis of GR1 indicated that the clustered positively charged amino acids in GR1 play important roles in Pol packaging. Our results suggest that GR1 contains a Pol interaction domain and that a Gag-Pol complex is formed and binds to RNA for incorporation into virions.     

Generation of a helper cell line for packaging avian leukosis virus-based vectors.

We constructed an avian leukosis virus-based packaging cell line, pHF-g, containing Rous-associated virus DNA with several alterations to abolish RNA packaging. One of them is a 52-base-pair deletion encompassing the putative encapsidation signal in the leader region. The 3' long terminal repeat was also removed and replaced by the polyadenylation sequence from the herpes simplex virus thymidine kinase gene. When pHF-g cells were transfected by an avian leukosis virus-based vector, they produced replication-defective virus at high titer but they did not release any replication-competent particles. Proviral DNA was shown to be correctly integrated as well as correctly expressed. Viral RNAs were shown to be correctly translated into gag-related polypeptides.     

Identification of a repeated sequence element required for efficient encapsidation of the adenovirus type 5 chromosome.

Adenovirus type 5 deletion mutants that lack portions of their cis-acting DNA encapsidation signal synthesized nearly normal levels of viral DNA and late polypeptides but failed to efficiently package the DNA into virus particles. A series of mutant viruses carrying small deletions were produced and used to identify a repeated element (AGTAAATTTGGGC and AGTAAGATTTGGCC) as a key component of the packaging signal. One copy of the repeat was sufficient to signal efficient packaging. The packaging domain could function near either end of the viral chromosome but was no longer active when moved several hundred base pairs toward the interior of the DNA molecule.     

cis and trans requirements for the selective packaging of adenovirus type 5 DNA.

Polar packaging of adenovirus DNA into virions is dependent on the presence of cis-acting sequences at the left end of the viral genome. Our previous analyses demonstrated that the adenovirus type 5 (Ad5) packaging domain (nucleotides 194 to 358) is composed of at least five elements that are functionally redundant. A repeated sequence, termed the A repeat, was associated with packaging function. Here we report a more detailed analysis of the requirements for the selective packaging of Ad5 DNA. By introducing site-directed point mutations into specific A repeat sequences, we demonstrate that the A repeats represent cis-acting functional components of the packaging signal. Additional elements, located outside the originally defined packaging domain boundaries and that resemble the A repeat consensus sequence, also are capable of promoting the packaging of viral DNA. The cis-acting components of the packaging signal appear to be subject to certain spatial constraints for function, possibly reflecting a necessity for the coordinate binding of packaging proteins to these sites. In agreement with this idea, we present evidence that the interaction of a limiting trans-acting factor(s) with the packaging domain in vivo is required for efficient encapsidation of the Ad5 genome.