Ribonucleoprotein (RNP) cores of influenza virus A/PR/8/34 were dissociated into RNA polymerase (PB1-PB2-PA complex)-associated genome RNA and nuclear protein (NP) fractions by CsCl centrifugation. The RNA polymerase-RNA complexes were capable of catalyzing the endonucleolytic cleavage of capped RNA, the initiation of primer-dependent RNA synthesis, and the synthesis of small-sized RNA, but were unable to synthesize template-sized RNA. By adding the NP protein to the RNA polymerase-RNA complexes, RNP (RNA polymerase-RNA-NP) complexes were reconstituted; they synthesized template-sized transcripts as did native RNP cores. These observations are consistent with the model where viral RNA polymerase is composed of the three P proteins while NP is essential for the elongation of RNA chains. RNP was completely dissociated into RNA-free proteins (PB1, PB2, PA, and NP) and a protein-free genome RNA fraction by centrifugation in cesium trifluoroacetate (CsTFA) and glycerol. By mixing the protein and RNA fractions, primer-dependent RNA-synthesizing activity was regained. These complexes, however, produced only small-sized RNA, presumably due to incorrect assembly of NP on viral RNA.
Influenza virus polymerase, which was prepared depleted of viral RNA, was used to copy small RNA templates prepared from plasmid-encoded sequences. Template constructions containing only the 3' end of genomic RNA were shown to be efficiently copied, indicating that the promoter lay solely within the 15-nucleotide 3' terminus. Sequences not specific for the influenza virus termini were not copied, and, surprisingly, RNAs containing termini identical to those from plus-sense cRNA were copied at low levels. The specificity for recognition of the virus sense promoter was further defined by site-specific mutagenesis. It was also found that increased levels of viral protein were required in order to catalyze both the cap endonucleaseprimed and primer-free RNA synthesis from these model templates, as well as from genomic-length RNAs. This finding indicates that the reconstituted system has catalytic properties very similar to those of native viral ribonucleoprotein complexes.
The RNA-dependent RNA polymerase of influenza virus A/PR/8 was isolated from virus particles by stepwise centrifugation in cesium salts. First, RNP (viral RNA-NP-P proteins) complexes were isolated by glycerol gradient centrifugation of detergent-treated viruses and subsequently NP was dissociated from RNP by cesium chloride gradient centrifugation. The P-RNA (P proteins-viral RNA) complexes were further dissociated into P proteins and viral RNA by cesium trifluoroacetate (CsTFA) gradient centrifugation. The nature of P proteins was further analyzed by glycerol gradient centrifugation and immunoblotting using monospecific antibodies against each P protein. The three P proteins, PB1, PB2, and PA, sedimented altogether as fast as the marker protein with the molecular weight of about 250,000 Da. Upon addition of the template vRNA, the RNA-free P protein complex exhibited the activities of capped RNA cleavage and limited RNA synthesis. When a cell line stably expressing cDNAs for three P proteins and NP protein was examined, the three P proteins were found to be co-precipitated by antibodies against the individual P proteins. These results indicate that the influenza virus RNA-dependent RNA polymerase is a heterocomplex composed of one each of the three P proteins and that the RNA-free RNA polymerase can be isolated in an active form from virus particles. Furthermore, the three P proteins form a complex in the absence of vRNA.
The RNA-dependent RNA polymerase of influenza virus is composed of three viral P proteins (PB1, PB2, and PA) and involved in both transcription and replication of the RNA genome. The PB1 subunit plays a key role in both the assembly of three P protein subunits and the catalytic function of RNA polymerization. We have established a simultaneous expression system of three P proteins in various combinations using recombinant baculoviruses, and isolated the PA-PB1-PB2 ternary (3P) complex and two kinds of the binary (2P) complex, PA-PB1 and PB1-PB2. The affinity-purified 3P complex showed all of the catalytic properties characteristic of the transcriptase, including capped RNA-binding, capped RNA cleavage, model viral RNA binding, model viral RNA-directed RNA synthesis, and polyadenylation of newly synthesized RNA. The PB1-PB2 binary complex showed essentially the same catalytic properties as does the 3P complex, whereas the PA-PB1 complex catalyzed de novo initiation of RNA synthesis in the absence of primers. Taken together we propose that the catalytic specificity of PB1 subunit is modulated to the transcriptase by binding PB2 or the replicase by interaction with PA. T he genome of influenza virus is composed of eight negativestrand viral RNA (vRNA) segments, which altogether encode 10 different viral proteins (1). The vRNA polymerase is involved in both transcription and replication (for reviews see refs. 2-4). In transcription, the RNA polymerase catalyzes not only RNA polymerization but also the cleavage of host cell mRNA to generate capped RNA primers (5-8) and polyadenylation of mRNA (9-11). The RNA polymerase also carries an apparent proofreading (12). The RNA polymerase is composed of one molecule each of three viral proteins, PB1, PB2 and PA (13). The PB1 protein plays central roles in both RNA polymerase assembly (14, 15), and RNA polymerization (16,17). The PB1 gene also encodes a short immunogenic peptide by the ϩ1 reading frame with killing activity of host immune cells (18). The PB2 subunit plays a role in recognition and binding of capped RNA for generation of primers for RNA synthesis (19-21). The consensus sequence for RNA cap-binding exists in this subunit (22), but the catalytic site for capped RNA cleavage was suggested to locate in PB1 (23). The function of PA remains unidentified, but mutations in the PA gene affect replication (reviewed in ref. 24).Because the content of RNA polymerase in virions is very low (1, 3, 4) and moreover it is tightly associated with vRNA (13), it is difficult to purify large amounts of the RNA polymerase. The efficiency of reconstitution in vitro is too low to get the RNA polymerase in active form (25,26). For the large-scale production, attempts have been made to develop expression systems of the recombinant RNA polymerase. The initial success was achieved by using a vaccinia virus and was used for in vivo studies (27,28). However, because of the low level of expression and the cytopathic effect of vaccinia virus vector, this system is not suitable for large-scal...
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
customersupport@researchsolutions.com
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.