Molecular cloning and characterization of the RNA packaging-defective retrovirus SE21Q1b.

The nonconditional RNA packaging mutant SE21Q1b contains cis- and trans-acting defects which cause cellular mRNA, rather than viral genomic RNA, to be nonspecifically packaged into SE21Q1b viral particles. Using genomic libraries of the c-SE21Q1b quail cell line, we have been able to construct a molecular clone of the SE21Q1b provirus. Upon transfection into primary quail embryo fibroblasts, the SE21Q1b molecular clone is able to recapitulate the nonspecific RNA packaging phenotype of the c-SE21Q1b cell line. The RNA packaging phenotypes displayed by several SE21Q1b/avian sarcoma-leukemia virus hybrid provirus constructs have further indicated that sequences responsible for the altered RNA packaging phenotype of SE21Q1b are localized in the left third of the SE21Q1b proviral genome. DNA sequence analysis of this region has revealed that the 5' SE21Q1b deletion has removed 179 bp from the SE21Q1b left long terminal repeat and leader regions. Several differences were detected at the carboxyl terminus of the deduced SE21Q1b nucleocapsid protein sequence in comparison with that of Rous sarcoma virus PR-C. Results of site-directed oligonucleotide mutagenesis experiments indicate, however, that the presence of these residues in the nucleocapsid protein alone is not responsible for the decreased RNA packaging specificity of SE21Q1b.     

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.     

A defective retrovirus particle (SE21Q1b) packages and reverse transcribes cellular RNA, utilizing tRNA-like primers.

Linial and co-workers described a quail cell line, SE21Q1b, transformed by a single provirus of Rous sarcoma virus that is defective in virus assembly, in as much as the virus particles produced, SE21, contain cellular rather than viral RNA. In other respects these particles are normal, and the amount of endogenous DNA synthesis by disrupted virus particles is comparable to that of normal virus. We now report that endogenous DNA synthesis by SE21 virions uses RNA primers of the same size as tRNA species and that about 17% of these are bound to polyadenylate-containing RNA templates. Previous studies have shown that with wild-type Rous sarcoma virus, DNA synthesis is exclusively initiated on a tRNATrp species base paired to a specific location on the viral RNA. In contrast, we interpreted our data with SE21 as evidence that many different tRNA-primed initiations occurred, that predominantly species other than tRNATrp were used, and that the base pairing between template and primer RNAs included significant nucleotide mismatching. A subpopulation of the DNA synthesized by SE21 virions from tRNA-like primers was both initiated and terminated at discrete locations. These species are therefore analogous to the strong-stop DNA synthesized by wild-type virus.     

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.     

An MΨ-Containing Heterologous RNA, but Not env mRNA, Is Efficiently Packaged into Avian Retroviral Particles

Retroviruses preferentially package full-length genomic RNA over spliced viral messages. For most retroviruses, this preference is likely due to the absence of all or part of the packaging signal on subgenomic RNAs. In avian leukosis-sarcoma virus, however, we have shown that the minimal packaging signal, MPsi, is located upstream of the 5' splice site and therefore is present on both genomic and spliced RNAs. We now show that an MPsi-containing heterologous RNA is packaged only 2.6-fold less efficiently than genomic Rous sarcoma virus RNA. Thus, few additional packaging sequences and/or structures exist outside of MPsi. In contrast, we found that env mRNA is not efficiently packaged. These results indicate that either MPsi is not functional on this RNA or the RNA is somehow segregated from the packaging machinery. Finally, deletion of sequences from the 3' end of MPsi was found to reduce the packaging efficiency of heterologous RNAs.     

Efficiency and selectivity of RNA packaging by Rous sarcoma virus Gag deletion mutants.

In all retrovirus systems studied, the leader region of the RNA contains a cis-acting sequence called psi that is required for packaging the viral RNA genome. Since the pol and env genes are dispensable for formation of RNA-containing particles, the gag gene product must have an RNA binding domain(s) capable of recognizing psi. To gain information about which portion(s) of Gag is required for RNA packaging in the avian sarcoma and leukemia virus system, we utilized a series of gag deletion mutants that retain the ability to assemble virus-like particles. COS cells were cotransfected with these mutant DNAs plus a tester DNA containing psi, and incorporation of RNA into particles were measured by RNase protection. The efficiency of packaging was determined by normalization of the amount of psi+ RNA to the amount of Gag protein released in virus-like particles. Specificity of packaging was determined by comparisons of psi+ and psi- RNA in particles and in cells. The results indicate that much of the MA domain, much of the p10 domain, half of the CA domain, and the entire PR domain of Gag are unnecessary for efficient packaging. In addition, none of these deleted regions is needed for specific selection of the psi RNA. Deletions within the NC domain, as expected, reduce or eliminate both the efficiency and the specificity of packaging. Among mutants that retain the ability to package, a deletion within the CA domain (which includes the major homology region) is the least efficient. We also examined particles of the well-known packaging mutant SE21Q1b. The data suggest that the random RNA packaging behavior of this mutant is not due to a specific defect but rather is the result of the cumulative effect of many point mutations throughout the gag gene.     

A base-paired structure in the avian sarcoma virus 5' leader is required for efficient encapsidation of RNA.

Selective encapsidation of avian sarcoma-leukosis virus genomic RNA within virions requires recognition of a cis-acting signal (termed psi) located in the 5' leader of the RNA between the primer binding site and the splice donor site. Computer analyses indicate the potential for numerous secondary structure interactions within this region, including alternative conformations with similar free energy levels. We have constructed mutations designed to disrupt and restore potential secondary structure interactions within psi to investigate the role of these structures in RNA packaging. To test for the ability of psi mutants to package a heterologous reporter gene into virions, chimeric constructs bearing avian sarcoma virus 5' sequences fused to lacZ were transiently cotransfected with a nonpackageable helper construct into chicken embryo fibroblasts. lacZ virions produced from cotransfected cells were used to infect new cultures of chicken embryo fibroblasts, and then an in situ assay for individual cells expressing lacZ was done. Results obtained with this assay were confirmed in direct analyses of isolated virion RNA by RNase protection assays. Two mutations, predicted to disrupt a potential stem structure forming between elements located at nucleotides 160 to 167 and 227 to 234, severely inhibited packaging when either element was mutated. A construct in which these mutations were combined to restore potential base pairing between the two elements displayed a partially restored packaging phenotype. These results strongly suggest that the structure, referred to as the O3 stem, is required for efficient encapsidation of avian sarcoma virus RNA. Site-directed mutagenesis of additional sequence elements located in the O3 loop reduced packaging as measured by the indirect assay, suggesting that these sequences may also be components of the encapsidation signal. The possible implications of the O3 stem structure with regard to translation of avian sarcoma-leukosis virus short upstream open reading frames are discussed.     

Retrotransposition of Nonviral RNAs in an Avian Packaging Cell Line

Retroviruses produced from the quail packaging cell line SE21Q1b predominantly contain cellular RNAs instead of viral RNAs. These RNAs can be reverse transcribed and integrated into the genomes of newly infected cells and are thereafter referred to as newly formed retrogenes. We investigated whether retrogene formation can occur within SE21Q1b cells themselves and whether this occurs intracellularly or via extracellular reinfection. By using packaging cell line mutants derived from the SE21Q1b provirus and selectable reporter constructs, we found that the process requires envelope glycoproteins and a retroviral packaging signal. Our results suggest that extracellular reinfection is the primary route of retrotransposition of nonviral RNAs.     

Transfer of defective avian tumor virus genomes by a Rous sarcoma virus RNA packaging mutant.

SE21Q1b, a Rous sarcoma virus mutant which packages cellular rather than viral RNA, is competent for infection of quail cells and can transmit defective transforming retrovirus genes. Stably transformed recipient clones have been obtained by using this mutant.     

Yeast three-hybrid screening of rous sarcoma virus mutants with randomly mutagenized minimal packaging signals reveals regions important for gag interactions

We previously showed that the yeast three-hybrid system provides a genetic assay of both RNA and protein components for avian retroviral RNA encapsidation. In the current study, we used this assay to precisely define cis-acting determinants involved in avian leukosis sarcoma virus packaging RNA binding to Gag protein. In vivo screening of Rous sarcoma virus mutants was performed with randomly mutated minimal packaging sequences (MPsi) made using PCR amplification after cotransformation with GagDeltaPR protein into yeast cells. Colonies with low beta-galactosidase activity were analyzed to locate mutations in MPsi sequences affecting binding to Gag proteins. This genetic assay delineated secondary structural elements that are important for efficient RNA binding, including a single-stranded small bulge containing the initiation codon for uORF3, as well as adjacent stem structures. This implies a possible tertiary structure favoring the high-affinity binding sites for Gag. In most cases, results from the three-hybrid assay were well correlated with those from the viral RNA packaging assays. The results from random mutagenesis using the rapid three-hybrid binding assay are consistent with those from site-directed mutagenesis using in vivo packaging assays.     

mRNA molecules containing murine leukemia virus packaging signals are encapsidated as dimers

Prior work by others has shown that insertion of psi (i.e., leader) sequences from the Moloney murine leukemia virus (MLV) genome into the 3' untranslated region of a nonviral mRNA leads to the specific encapsidation of this RNA in MLV particles. We now report that these RNAs are, like genomic RNAs, encapsidated as dimers. These dimers have the same thermostability as MLV genomic RNA dimers; like them, these dimers are more stable if isolated from mature virions than from immature virions. We characterized encapsidated mRNAs containing deletions or truncations of MLV psi or with psi sequences from MLV-related acute transforming viruses. The results indicate that the dimeric linkage in genomic RNA can be completely attributed to the psi region of the genome. While this conclusion agrees with earlier electron microscopic studies on mature MLV dimers, it is the first evidence as to the site of the linkage in immature dimers for any retrovirus. Since the Psi(+) mRNA is not encapsidated as well as genomic RNA, it is only present in a minority of virions. The fact that it is nevertheless dimeric argues strongly that two of these molecules are packaged into particles together. We also found that the kissing loop is unnecessary for this coencapsidation or for the stability of mature dimers but makes a major contribution to the stability of immature dimers. Our results are consistent with the hypothesis that the packaging signal involves a dimeric structure in which the RNAs are joined by intermolecular interactions between GACG loops.     

Specificity of Rous sarcoma virus nucleocapsid protein in genomic RNA packaging.

Site-directed mutagenesis has shown that the nucleocapsid (NC) protein of Rous sarcoma virus (RSV) is required for packaging and dimerization of viral RNA. However, it has not been possible to demonstrate, in vivo or in vitro, specific binding of viral RNA sequences by NC. To determine whether specific packaging of viral RNA is mediated by NC in vivo, we have constructed RSV mutants carrying sequences of Moloney murine leukemia virus (MoMuLV). Either the NC coding region alone, the psi RNA packaging sequence, or both the NC and psi sequences of MoMuLV were substituted for the corresponding regions of a full-length RSV clone to yield chimeric plasmid pAPrcMNC, pAPrc psi M, or pAPrcM psi M, respectively. In addition, a mutant of RSV in which the NC is completely deleted was tested as a control. Upon transfection, each of the chimeric mutants produced viral particles containing processed core proteins but were noninfectious. Thus, MoMuLV NC can replace RSV NC functionally in the assembly and release of mature virions but not in infectivity. Surprisingly, the full-deletion mutant showed a strong block in virus release, suggesting that NC is involved in virus assembly. Mutant PrcMNC packaged 50- to 100-fold less RSV RNA than did the wild type; in cotransfection experiments, MoMuLV RNA was preferentially packaged. This result suggests that the specific recognition of viral RNA during virus assembly involves, at least in part, the NC protein.