Sequences in the 5' leader of Mason-Pfizer monkey virus which affect viral particle production and genomic RNA packaging: development of MPMV packaging cell lines.

We used a series of deletion mutations in the 5' untranslated region of the prototype D type retrovirus, Mason-Pfizer Monkey Virus (MPMV), to analyse RNA encapsidation. A region was identified upstream of the major splice donor which reduced particle production but had a proportionally greater effect on RNA packaging. A small deletion downstream of the splice donor had little effect on RNA production and caused no significant packaging defect. A large deletion encompassing the end of the primer binding site down to the splice donor had a dramatic effect, disrupting viral protein synthesis. Stable cell lines were produced containing packaging-defective virus. These first-generation packaging cell lines were used to package and transfer an MPMV-based vector.     

Sequences within the gag gene of feline immunodeficiency virus (FIV) are important for efficient RNA encapsidation

Feline immunodeficiency virus (FIV)-based retroviral vector systems are being developed for human gene therapy. Consequently, it has become important to know the precise sequence requirements for the packaging of FIV genome so that such sequences can be eliminated from transfer vectors post-transduction for improved safety. Recently, we have shown that sequences both within the 5'-untranslated leader region (UTR) and the 5'-end of gag are required for efficient packaging and transduction of FIV-based vectors. However, the extent of gag sequence important in the encapsidation process is not clear as well as their relative contribution to packaging. In this study, using a biologically relevant packaging system, we demonstrate that at the most 100 bp of gag sequences are sufficient for efficient RNA packaging in conjunction with the 5'-UTR and no other sequences within the next 600 bp of gag exist that affect packaging. In addition, we show that sequences within gag do not simply act as spatial elements to stabilize other structural determinants of packaging located within the 5'-UTR, but are important in themselves for the encapsidation process.     

The critical role of proximal gag sequences in feline immunodeficiency virus genome encapsidation

Retroviral RNA encapsidation is mediated by specific interactions between viral Gag proteins and cis-acting packaging sequences in genomic RNA. Feline immunodeficiency virus (FIV) RNA encapsidation determinants have been shown to be discrete and noncontinuous, comprising one region at the 5' end of the genomic mRNA (R-U5) and another region that mapped within the proximal 311 nt of gag. To aid comparative understanding of lentiviral encapsidation and refinement of FIV vector systems, we used RNase protection assays (RPAs) of cellular and virion RNAs to investigate in detail the gag element. mRNAs of subgenomic vectors as well as of full-length molecular clones were optimally packaged into viral particles and resulted in high-titer FIV vectors when they contained only the proximal 230 nucleotides (nt) of gag. Further 3' truncations of gag sequences progressively diminished encapsidation and transduction. Deletion of the initial ninety 5' nt of the gag gene abolished mRNA packaging, demonstrating that this segment is indispensable for encapsidation. Focusing further on this proximal sequence, we found that a deletion of only 13 nt at the 5' end of gag impaired encapsidation of subgenomic vector and proviral RNAs.     

Mutational analysis of the predicted secondary RNA structure of the Mason-Pfizer monkey virus packaging signal

The 5' end of the Mason-Pfizer monkey virus (MPMV) genomic RNA has been predicted to fold into a complex stem/loop structure that is thought to play a role in specific RNA encapsidation. In this study, we used a set of mutations that either abrogated or recreated the first four stem loops predicted within the 5' untranslated region (5' UTR) for effects on RNA packaging. Test of these mutations in our biological assay revealed that only stem loop 1 (SL1) was important for the packaging potential of MPMV, while mutations in none of the other stem loops affected packaging significantly. Interestingly, it was the primary sequence of SL1 RNA and not its secondary structure that affected packaging since compensatory mutations that reformed SL1 were unable to restore the packaging efficiency of the retroviral vector. Additionally, our mutational analysis reveals that stem loop 4, predicted to be the major packaging determinant of MPMV, does not seem to have a significant role in packaging. Finally, results of the biological effects of the structural mutations are discussed in relation to their effects on the folding potential of the various stem loops.     

Identification of a sequence likely to be required for avian retroviral packaging

Two assays have been utilized to assess the ability of avian retroviral molecules to be packaged into virus particles. Cloned viral genomic molecules were microinjected into the nuclei of chick cells infected by either a lymphoid leukosis virus or an envelope glycoprotein-deficient sarcoma virus. The titer of focus-forming virus released by injected cells, or the ratio of these to helper virus, is then used to determine packaging efficiency, although biological properties other than packaging might also effect these assays. With either assay, deletions up to 3.0 kbp introduced in the viral gag or pol genes did not affect packaging unless sequences near the SstII restriction site (approximately 150 bp 3' of the splice donor site) were deleted. Deletions differing by 2 bp at the SstII site were found to express radically different packaging efficiencies.     

Deletion of stem-loop 3 is compensated by second-site mutations within the Gag protein of human immunodeficiency virus type 1

Encapsidation of human immunodeficiency virus type 1 (HIV-1) RNA involves specific interactions between viral Gag proteins and viral RNA elements located at the 5' untranslated region (UTR). These RNA elements are termed packaging (psi) or encapsidation (E) signals and mainly comprise the stem-loop 1 (SL1) and SL3 RNA structures. We have previously shown that deletion of the SL1 sequences is compensated by second-site mutations within Gag. Similar studies are now extended to SL3 and the results demonstrate that deletion of this RNA structure is rescued by two point mutations, i.e., A11V in p2 and I12V in nucleocapsid (NC). These two compensatory mutations are different from those associated with the rescue of SL1 deletion, suggesting that SL1 and SL3 may bind to different residues of Gag during viral RNA packaging. Analysis of virion-derived RNA in native agarose gels shows that deletion of SL3 leads to decreases in both viral RNA packaging and dimerization. These defects are corrected by the compensatory mutations A11V and I12V. Yet, defects in viral RNA dimerization at an early stage that were caused by the SL3 deletion in the context of a viral protease-negative mutation cannot be overcome by these two suppressor mutations. Therefore, the positive effects of A11V and I12V on dimerization of the SL3-deleted RNA must have taken place at the maturation stage.     

The 5′-UTR of Turnip yellow mosaic virus does not include a critical encapsidation signal

Turnip yellow mosaic virus (TYMV) RNA has two hairpins in the 5′ untranslated region (UTR) with internal CC and CA mismatches that become protonated and are able to base pair at a pH near 5. The protonatable hairpins have previously been implicated as playing an important role in RNA encapsidation. We have examined the role of the 5′-UTR in the amplification and packaging of TYMV RNA using agroinfiltration of Chinese cabbage leaves to express various TYMV constructs with mutations affecting the 5′-UTR and the two hairpins. Mutations affecting the protonatable centers of the two hairpins, as well as deletion of one or both hairpins and deletion or mutation of the 17-nucleotide region upstream of the hairpins decreased viral amplification to varying extents (c. 10- to 1000-fold). However, in all these cases, the viral RNAs present in non-denaturing leaf extracts were predominantly ribonuclease resistant, indicative of encapsidation. These results show that, while the 5′ hairpins are necessary for efficient amplification of TYMV, there appears to be no essential role for the 5′-UTR or its protonatable hairpins in the packaging of TYMV RNA. In a second set of experiments, it was demonstrated that TYMV can efficiently amplify in plants held in the dark, and that the progeny RNAs are efficiently encapsidated. Together, these observations argue for a revision of the model for TYMV encapsidation in which packaging occurs in low pH conditions that are generated by proton gradients produced by photosynthetic activity in the light and RNA packaging is dependent on the protonatable 5′ hairpins.     

Nucleotide sequence analysis of the chicken gene c-mil, the progenitor of the retroviral oncogene v-mil

The nucleotide sequence of the chicken gene c-mil was determined within and around all regions homologous to the oncogene v-mil of avian retrovirus MH2. The regions of homology to the previously determined v-mil sequence, ranging in size from 28 to 177 base pairs (bp), are distributed over 14 kilobase pairs (kbp) of the chicken genome and are organized in 11 exons. All exon-intron boundaries of c-mil, except the 5' boundary of exon 1 and the 3' boundary of exon 11, were unambiguously defined by the identification of consensus splice donor and acceptor sites precisely at positions where homology to v-mil ceases or resumes. The homology to v-mil starts within the coding sequence of exon 1 and ends within the 3' untranslated region of exon 11, 12 nucleotides downstream from the nonsense codon terminating the large open reading frame shared between c-mil and v-mil. The c-mil and v-mil sequences differ at only 7 out of 1153 nucleotide positions, and the predicted sequences of v-mil and c-mil proteins differ by one conservative and four nonconservative substitutions among 379 amino acid residues. Hence, the carboxy-terminal domains of the MH2 gag-mil hybrid protein and of the putative c-mil protein are very similar. However, the amino-terminal domain of the cellular protein is possibly encoded by additional 5' c-mil sequences not present in the transduced v-mil oncogene, while that of the MH2 hybrid protein is encoded by viral gag sequences. The sequence analysis also revealed that c-mil and c-myc derived sequences are immediately adjacent on the MH2 genome carrying both the v-mil and the v-myc oncogene. Hence, transduction of c-mil into MH2 involved recombination, at the 3' site, with either the c-myc locus or a previously transduced v-myc gene, and, at the 5' site, with gag sequences of the transducing virus. At both sites, no significant homologies were found between the sequence elements involved in the recombination.     

The 5' ends of the transforming gene of Fujinami sarcoma virus and of the cellular proto-fps gene are not colinear

The sequence of 500 nucleotides of a cellular proto-fps region that includes the 5' boundary of overlap with the fps sequence of Fujinami sarcoma virus (FSV) was determined. It was found that the potential reading frame of the proto-fps region continues over the 5' boundary of overlap with viral fps for 44 codons which do not include an AUG translation initiation codon. A potential upstream exon of proto-fps of over 91 codons and a potential splice acceptor at the site of fps/proto-fps overlap have been identified. It is concluded that the boundary of overlap between proto-fps and viral fps cannot represent the 5' end of the coding region of proto-fps. The proto-fps gene starts either in the upstream exon(s) not shared with FSV or at least 51 codons downstream of the boundary of overlap with FSV. In addition, the 5' coding region of proto-fps differs from the (delta gag-fps) hybrid transforming gene of FSV in the absence of the retroviral gag gene-derived sequence.     

Construction of retroviral vectors with enhanced efficiency of transgene expression

Retroviral vectors have been widely used in gene therapy due to their simple genomic structure and high transduction efficiency. We report a construction of Moloney murine sarcoma virus (MoMSV) and Moloney murine leukemia virus (MoMLV) hybrid-based retroviral vectors with significantly improved efficiency of transgene expression after stable incorporation into the host genome. In these vectors, the residual gag gene coding sequence located in the extended region of packaging signal was removed. These vectors, therefore, contain no coding sequence for the gag, pol, or env gene that can be used for homologous recombination with sequences introduced in the packaging system for a recombinant competent retrovirus (RCR) generation. A strong splice acceptor site obtained from the exon/intron junction of either the chimpanzee EF1-alpha gene or the human CMV major immediate early gene was placed downstream of the MoMSV packaging signal (Psi), significantly improving the efficiency of transgene expression. The 5' LTR U3 sequence was replaced with an extended human CMV major immediate early gene enhancer/promoter for a strong expression of full-length messages from the viral backbone, helping to maintain high levels of viral titer. These newly developed retroviral vectors should facilitate RCR-free gene transfer with significantly improved efficacy in clinical gene therapy trials.