Effects of Gag mutation and processing on retroviral dimeric RNA maturation

After their release from host cells, most retroviral particles undergo a maturation process, which includes viral protein cleavage, core condensation, and increased stability of the viral RNA dimer. Inactivating the viral protease prevents protein cleavage; the resulting virions lack condensed cores and contain fragile RNA dimers. Therefore, protein cleavage is linked to virion morphological change and increased stability of the RNA dimer. However, it is unclear whether protein cleavage is sufficient for mediating virus RNA maturation. We have observed a novel phenotype in a murine leukemia virus capsid mutant, which has normal virion production, viral protein cleavage, and RNA packaging. However, this mutant also has immature virion morphology and contains a fragile RNA dimer, which is reminiscent of protease-deficient mutants. To our knowledge, this mutant provides the first evidence that Gag cleavage alone is not sufficient to promote RNA dimer maturation. To extend our study further, we examined a well-defined human immunodeficiency virus type 1 (HIV-1) Gag mutant that lacks a functional PTAP motif and produces immature virions without major defects in viral protein cleavage. We found that the viral RNA dimer in the PTAP mutant is more fragile and unstable compared with those from wild-type HIV-1. Based on the results of experiments using two different Gag mutants from two distinct retroviruses, we conclude that Gag cleavage is not sufficient for promoting RNA dimer maturation, and we propose that there is a link between the maturation of virion morphology and the viral RNA dimer.     

Capsid protein synthesis from replicating RNA directs specific packaging of the genome of a multipartite, positive-strand RNA virus

Flock house virus (FHV) is a bipartite, positive-strand RNA insect virus that encapsidates its two genomic RNAs in a single virion. It provides a convenient model system for studying the principles underlying the copackaging of multipartite viral RNA genomes. In this study, we used a baculovirus expression system to determine if the uncoupling of viral protein synthesis from RNA replication affected the packaging of FHV RNAs. We found that neither RNA1 (which encodes the viral replicase) nor RNA2 (which encodes the capsid protein) were packaged efficiently when capsid protein was supplied in trans from nonreplicating RNA. However, capsid protein synthesized in cis from replicating RNA2 packaged RNA2 efficiently in the presence and absence of RNA1. These results demonstrated that capsid protein translation from replicating RNA2 is required for specific packaging of the FHV genome. This type of coupling between genome replication and translation and RNA packaging has not been observed previously. We hypothesize that RNA2 replication and translation must be spatially coordinated in FHV-infected cells to facilitate retrieval of the viral RNAs for encapsidation by newly synthesized capsid protein. Spatial coordination of RNA and capsid protein synthesis may be key to specific genome packaging and assembly in other RNA viruses.     

Ribonucleic Acid and protein synthesis in chick embryo cells infected with fowl plague virus

Fowl plague virus comprised four major protein components and several minor ones, two strains of the virus giving similar results. One of the components was identified as the nucleocapsid protein. Synthesis of the virion proteins could readily be detected in infected cells 3 hr after infection. The two subcellular fractions associated with viral ribonucleic acid (RNA) polymerase activity (nuclei and ribosomal pellet) were associated with the protein of the nucleocapsid and a second virion protein of unidentified function. Measurement of viral RNA and protein synthesis in cells infected with preparations of ultraviolet irradiated virus showed that the capacity to synthesise the RNA and protein species of highest molecular weight was lost most quickly, suggesting that the pieces of viral RNA function independently.     

Specific binding of the type C viral core protein p12 with purified viral RNA.

The major viral phosphoproteins (p12) of the Rauscher murine leukemia virus (R-MuLV) and the simian sarcoma-associated virus (SSAV) bind in vitro to their homologous 70S and 35S viral RNAs. Using purified 32P-labeled RNA and 125I-labeled p12 protein, complexes that are stabilized by formaldehyde-cross-linking can be readily detected after velocity gradient centrifugation. The in vitro reconstructed ribonucleoprotein complexes are seen only with p12 proteins incubated with viral RNAs isolated from the same type C viruses; no such complexes form with heterologous protein-RNA mixtures. Homologous but not heterologous p12 molecules compete with radiolabeled p12 protein for the specific viral RNA binding sites. The competition assay permits the detection of 10 ng of viral p12 protein. The major internal protein of type C viruses (p30) does not bind to viral RNA using identical assay conditions. From the specific activities of the radiolabeled components and also by equilibrium sedimentation analysis, we estimate that fewer than 15 molecules of p12 protein bind to each molecule of viral RNA. Both the specificity and stoichiometry of the p12-RNA interactions suggest that these RNA tumor virus proteins have a regulatory role in cells.     

It is Rous sarcoma virus protein P12 and not P19 that binds tightly to Rous sarcoma virus RNA

The interactions between Rous Sarcoma virus (RSV) RNA and the viral proteins in the virus have been analysed by Sen & Todaro (1977) using ultraviolet light irradiation; they showed that the major protein ultraviolet light cross-linked to the viral RNA was P19 as identified by polyacrylamide gel electrophoresis. We report here that it is not viral protein P19 but P12 that binds tightly to RSV RNA upon ultraviolet light irradiation of the virus. Therefore, the binding sites of the viral protein along RSV RNA that we have characterized previously should be correctly attributed now to P12 and not P19.     

A splice hepadnavirus RNA that is essential for virus replication.

According to the current model of hepadnavirus gene expression, the viral envelope proteins are produced from unspliced subgenomic RNAs, in contrast to the retroviral mechanism, where the subgenomic env RNA is generated by RNA splicing. We now describe and characterize a novel duck hepatitis B virus RNA species which is derived from the RNA pregenome by loss of a 1.15 kb intron. This RNA (termed spliced L RNA) codes for the large surface protein (L protein), as does the previously described unspliced mRNA (the preS RNA); however, it differs in 5' leader sequence and promoter control. Mutational analysis indicates that the spliced L RNA is functionally important for virus replication in infected hepatocytes and ducks, but not for virus formation from transfected DNA genomes. This suggests that the newly discovered second pathway for L protein synthesis plays a distinct role in an early step in the viral life cycle.     

Specific RNA binding by amino-terminal peptides of alfalfa mosaic virus coat protein.

Specific RNA-protein interactions and ribonucleoprotein complexes are essential for many biological processes, but our understanding of how ribonucleoprotein particles form and accomplish their biological functions is rudimentary. This paper describes the interaction of alfalfa mosaic virus (A1MV) coat protein or peptides with viral RNA. A1MV coat protein is necessary both for virus particle formation and for the initiation of replication of the three genomic RNAs. We have examined protein determinants required for specific RNA binding and analyzed potential structural changes elicited by complex formation. The results indicate that the amino-terminus of the viral coat protein, which lacks primary sequence homology with recognized RNA binding motifs, is both necessary and sufficient for binding to RNA. Circular dichroism spectra and electrophoretic mobility shift experiments suggest that the RNA conformation is altered when amino-terminal coat protein peptides bind to the viral RNA. The peptide--RNA interaction is functionally significant because the peptides will substitute for A1MV coat protein in initiating RNA replication. The apparent conformational change that accompanies RNA--peptide complex formation may generate a structure which, unlike the viral RNA alone, can be recognized by the viral replicase.     

Encapsidation of Sendai virus genome RNAs by purified NP protein during in vitro replication.

The ability of the Sendai virus major nucleocapsid protein, NP, to support the in vitro synthesis and encapsidation of viral genome RNA during Sendai virus RNA replication was studied. NP protein was purified from viral nucleocapsids isolated from Sendai virus-infected BHK cells and shown to be a soluble monomer under the reaction conditions used for RNA synthesis. The purified NP protein alone was necessary and sufficient for in vitro genome RNA synthesis and encapsidation from preinitiated intracellular Sendai virus defective interfering particle (DI-H) nucleocapsid templates. The amount of DI-H RNA replication increased linearly with the addition of increasing amounts of NP protein. With purified detergent-disrupted DI-H virions as the template, however, there was no genome RNA synthesis in either the absence or presence of the NP protein. Furthermore, addition of the soluble protein fraction of uninfected cells alone or in the presence of purified NP protein also did not support DI-H genome RNA synthesis from purified DI-H. Another viral component in addition to the NP protein appears to be required for the initiation of encapsidation, since the soluble protein fraction of infected but not uninfected cells did support DI-H genome replication from purified DI-H.     

小麦丛矮病毒NS蛋白的磷酸化

小麦丛矮病毒是在中国发现的一种植物弹状病毒 ,病毒基因组是由一条单链负链RNA组成并编码 5种病毒结构蛋白质 :表面糖蛋白G、膜基质蛋白M、核衣壳蛋白N、大蛋白L和所谓非结构蛋白NS。后来的研究证明 ,在弹状病毒的模式病毒———水泡性口膜炎病毒中 ,NS蛋白也是一种结构蛋白 ,而且在成熟的病毒粒子中以各种磷酸化形式存在 ,并且证明NS的磷酸化和去磷酸化对病毒基因组的转录和复制的调控起重要的作用。用体外磷酸化方法证明 ,结合于小麦丛矮病毒的核衣壳上的NS蛋白可以被磷酸化 ;同时也证明 ,从大肠杆菌中表达的小麦丛矮病毒的NS蛋白 ,只有在病毒核衣壳存在下才可以体外被磷酸化 ;从而证明 ,小麦丛矮病毒或植物弹状病毒的NS蛋白也是一种磷酸化蛋白质 ,在成熟病毒粒子中可能存在磷酸化和非磷酸化两种形式。病毒的L蛋白除以前报道的具有RNA聚合酶活力外 ,也具有蛋白激酶的活力。     

The Interactomes of Influenza Virus NS1 and NS2 Proteins Identify New Host Factors and Provide Insights for ADAR1 Playing a Supportive Role in Virus Replication

Influenza A NS1 and NS2 proteins are encoded by the RNA segment 8 of the viral genome. NS1 is a multifunctional protein and a virulence factor while NS2 is involved in nuclear export of viral ribonucleoprotein complexes. A yeast two-hybrid screening strategy was used to identify host factors supporting NS1 and NS2 functions. More than 560 interactions between 79 cellular proteins and NS1 and NS2 proteins from 9 different influenza virus strains have been identified. These interacting proteins are potentially involved in each step of the infectious process and their contribution to viral replication was tested by RNA interference. Validation of the relevance of these host cell proteins for the viral replication cycle revealed that 7 of the 79 NS1 and/or NS2-interacting proteins positively or negatively controlled virus replication. One of the main factors targeted by NS1 of all virus strains was double-stranded RNA binding domain protein family. In particular, adenosine deaminase acting on RNA 1 (ADAR1) appeared as a pro-viral host factor whose expression is necessary for optimal viral protein synthesis and replication. Surprisingly, ADAR1 also appeared as a pro-viral host factor for dengue virus replication and directly interacted with the viral NS3 protein. ADAR1 editing activity was enhanced by both viruses through dengue virus NS3 and influenza virus NS1 proteins, suggesting a similar virus-host co-evolution.     

Role of the gag polyprotein precursor in packaging and maturation of Rous sarcoma virus genomic RNA.

Rous sarcoma virus nucleocapsid protein (NC) has been shown by site-directed mutagenesis to be involved in viral RNA packaging and in the subsequent maturation of genomic RNA in the progeny viral particles. To investigate whether NC exerts these activities as a free protein or as a domain of the polyprotein precursor Pr76gag, we have constructed several mutants unable to process Pr76gag and analyzed their properties in a transient-transfection assay of chicken embryo fibroblasts, the natural host of Rous sarcoma virus. A point mutation in the protease (PR) active site completely prevents Pr76gag processing. The full-length Pr76gag polyprotein is still able to package viral RNA, but cannot mature it. A shorter gag precursor polyprotein lacking the C-terminal PR domain, but retaining that of the NC protein, is however, unable even to package viral RNA. This indicates that the NC protein can participate in packaging viral RNA only as part of a full-length Pr76gag and that the PR domain is, indirectly or directly, also involved in RNA packaging. These results also demonstrate that processing of Pr76gag is necessary for viral RNA dimerization.     

Persistence of bovine viral diarrhea virus is determined by a cellular cofactor of a viral autoprotease

Polyprotein processing control is a crucial step in the life cycle of positive-strand RNA viruses. Recently, a vital autoprotease generating an essential viral replication factor was identified in such a virus, namely, the pestivirus bovine viral diarrhea virus. Surprisingly, the activity of this protease, which resides in nonstructural protein 2 (NS2), diminishes early after infection, resulting in the limitation of viral RNA replication. Here, we describe that a cellular chaperone termed Jiv (J-domain protein interacting with viral protein) acts as a cofactor of the NS2 protease. Consumption of the intracellular Jiv pool is responsible for temporal regulation of protease activity: overexpression of Jiv interfered with regulation and correlated with increased accumulation of viral RNA; downregulation of the cellular Jiv level accelerated the decline of protease activity and reduced intracellular viral RNA levels and virion production. Accordingly, the amount of a cellular protein controls pestiviral replication by limiting the generation of active viral protease molecules and replication complexes. Importantly, this unique mechanism of replication control is essential for maintenance of the noncytopathogenic phenotype of the virus and thereby for its ability to establish persistent infections. These results add an entirely novel aspect to the understanding of the molecular basis of viral persistence.     

A plant viral coat protein RNA binding consensus sequence contains a crucial arginine.

A defining feature of alfalfa mosaic virus (AMV) and ilarviruses [type virus: tobacco streak virus (TSV)] is that, in addition to genomic RNAs, viral coat protein is required to establish infection in plants. AMV and TSV coat proteins, which share little primary amino acid sequence identity, are functionally interchangeable in RNA binding and initiation of infection. The lysine-rich amino-terminal RNA binding domain of the AMV coat protein lacks previously identified RNA binding motifs. Here, the AMV coat protein RNA binding domain is shown to contain a single arginine whose specific side chain and position are crucial for RNA binding. In addition, the putative RNA binding domain of two ilarvirus coat proteins, TSV and citrus variegation virus, is identified and also shown to contain a crucial arginine. AMV and ilarvirus coat protein sequence alignment centering on the key arginine revealed a new RNA binding consensus sequence. This consensus may explain in part why heterologous viral RNA-coat protein mixtures are infectious.