The sequences of reovirus serotype 3 genome segments M1 and M3 encoding the minor protein mu 2 and the major nonstructural protein mu NS, respectively

Mammalian orthoreovirus core protein μ2 reorganizes host microtubule-organizing center components

Filamentous mammalian orthoreovirus (MRV) viral factories (VFs) are membrane-less cytosolic inclusions in which virus transcription, replication of dsRNA genome segments, and packaging of virus progeny into newly synthesized virus cores take place. In infected cells, the MRV μ2 protein forms punctae in the enlarged region of the filamentous VFs that are co-localized with γ-tubulin and resistant to nocodazole treatment, and permitted microtubule (MT)-extension, features common to MT-organizing centers (MTOCs). Using a previously established reconstituted VF model, we addressed the functions of MT-components and MTOCs concerning their roles in the formation of filamentous VFs. Indeed, the MTOC markers γ-tubulin and centrin were redistributed within the VF-like structures (VFLS) in a μ2-dependent manner. Moreover, the MT-nucleation centers significantly increased in numbers, and γ-tubulin was pulled-down in a binding assay when co-expressed with histidine-tagged-μ2 and μNS. Thus, μ2, by interaction with γ-tubulin, can modulate MTOCs localization and function according to viral needs.

Viral Protein Kinetics of Piscine Orthoreovirus Infection in Atlantic Salmon Blood Cells

Piscine orthoreovirus (PRV) is ubiquitous in farmed Atlantic salmon (Salmo salar) and the cause of heart and skeletal muscle inflammation. Erythrocytes are important target cells for PRV. We have investigated the kinetics of PRV infection in salmon blood cells. The findings indicate that PRV causes an acute infection of blood cells lasting 1-2 weeks, before it subsides into persistence. A high production of viral proteins occurred initially in the acute phase which significantly correlated with antiviral gene transcription. Globular viral factories organized by the non-structural protein µNS were also observed initially, but were not evident at later stages. Interactions between µNS and the PRV structural proteins λ1, µ1, σ1 and σ3 were demonstrated. Different size variants of µNS and the outer capsid protein µ1 appeared at specific time points during infection. Maximal viral protein load was observed five weeks post cohabitant challenge and was undetectable from seven weeks post challenge. In contrast, viral RNA at a high level could be detected throughout the eight-week trial. A proteolytic cleavage fragment of the µ1 protein was the only viral protein detectable after seven weeks post challenge, indicating that this µ1 fragment may be involved in the mechanisms of persistent infection.

Identification and characterization of two cleavage fragments from the Aquareovirus nonstructural protein NS80

Aquareovirus species vary with respect to pathogenicity, and the nonstructural protein NS80 of aquareoviruses has been implicated in the regulation of viral replication and assembly, which can form viral inclusion bodies (VIBs) and recruit viral proteins to its VIBs in infected cells. NS80 consists of 742 amino acids with a molecular weight of approximately 80 kDa. Interestingly, a short specific fragment of NS80 has also been detected in infected cells. In this study, an approximately 58-kDa product of NS80 was confirmed in various infected and transfected cells by immunoblotting analyses using α-NS80C. Mutational analysis and time course expression assays indicated that the accumulation of the 58-kDa fragment was related to time and infection dose, suggesting that the fragment is not a transient intermediate of protein degradation. Moreover, another smaller fragment with a molecular mass of approximately 22 kDa was observed in transfected and infected cells by immunoblotting with a specific anti-FLAG monoclonal antibody or α-NS80N, indicating that the 58- kDa polypeptide is derived from a specific cleavage site near the amino terminus of NS80. Additionally, different subcellular localization patterns were observed for the 22-kDa and 58-kDa fragments in an immunofluorescence analysis, implying that the two cleavage fragments of NS80 function differently in the viral life cycle. These results provide a basis for additional studies of the role of NS80 played in replication and particle assembly of the Aquareovirus.

[Orthoreoviruses]

Members of the genus Orthoreovirus in the family Reoviridae are nonenveloped, icosahedral viruses. Their genomes contain 10 segments of double-stranded RNA (dsRNA). The orthoreoviruses are divided into two subgroups, the fusogenic and nonfusogenic reoviruses, based on the ability of the virus to induce cell-to-cell fusion. The fusogenic subgroup consists of the avian reovirus, baboon reovirus, pteropine reovirus, and reptilian reovirus, whereas the nonfusogenic subgroup consists of the prototypical mammalian reovirus (MRV) species. MRVs are highly tractable experimental models for studies of segmented dsRNA virus replication and pathogenesis. Moreover, MRVs can selectively kill tumor cells and have been evaluated as oncolytic agents in clinical trials. This review provides a brief overview of current knowledge on the virological features of MRVs.

Sequence analysis of the genome of piscine orthoreovirus (PRV) associated with heart and skeletal muscle inflammation (HSMI) in Atlantic salmon (Salmo salar)

Piscine orthoreovirus (PRV) is associated with heart- and skeletal muscle inflammation (HSMI) of farmed Atlantic salmon (Salmo salar). We have performed detailed sequence analysis of the PRV genome with focus on putative encoded proteins, compared with prototype strains from mammalian (MRV T3D)- and avian orthoreoviruses (ARV-138), and aquareovirus (GCRV-873). Amino acid identities were low for most gene segments but detailed sequence analysis showed that many protein motifs or key amino acid residues known to be central to protein function are conserved for most PRV proteins. For M-class proteins this included a proline residue in μ2 which, for MRV, has been shown to play a key role in both the formation and structural organization of virus inclusion bodies, and affect interferon-β signaling and induction of myocarditis. Predicted structural similarities in the inner core-forming proteins λ1 and σ2 suggest a conserved core structure. In contrast, low amino acid identities in the predicted PRV surface proteins μ1, σ1 and σ3 suggested differences regarding cellular interactions between the reovirus genera. However, for σ1, amino acid residues central for MRV binding to sialic acids, and cleavage- and myristoylation sites in μ1 required for endosomal membrane penetration during infection are partially or wholly conserved in the homologous PRV proteins. In PRV σ3 the only conserved element found was a zinc finger motif. We provide evidence that the S1 segment encoding σ3 also encodes a 124 aa (p13) protein, which appears to be localized to intracellular Golgi-like structures. The S2 and L2 gene segments are also potentially polycistronic, predicted to encode a 71 aa- (p8) and a 98 aa (p11) protein, respectively. It is concluded that PRV has more properties in common with orthoreoviruses than with aquareoviruses.

Nonstructural protein NS80 is crucial in recruiting viral components to form aquareoviral factories

Background

Replication and assembly of vertebrate reoviruses occur in specific intracellular compartments known as viral factories. Recently, NS88 and NS80, the nonstructural proteins from aquareoviruses, have been proposed to share common traits with µNS from orthoreoviruses, which are involved in the formation of viral factories.

Methodology/Principal Findings

In this study, the NS80 characteristics and its interactions with other viral components were investigated. We observed that the NS80 structure ensured its self-aggregation and selective recruitment of viral proteins to viral factories like structures (VFLS). The minimum amino acids (aa) of NS80 required for VFLS formation included 193 aa at the C-terminal. However, this truncated protein only contained one aa coil and located in the nucleus. Its N-terminal residual regions, aa 1–55 and aa 55–85, were required for recruiting viral nonstructural protein NS38 and structural protein VP3, respectively. A conserved N-terminal region of NS38, which was responsible for the interaction with NS80, was also identified. Moreover, the minimal region of C-terminal residues, aa 506–742 (Δ505), required for NS80 self-aggregation in the cytoplasm, and aa 550–742 (Δ549), which are sufficient for recruiting viral structure proteins VP1, VP2, and VP4 were also identified.

Conclusions/Significance

The present study shows detailed interactions between NS80 and NS38 or other viral proteins. Sequence and structure characteristics of NS80 ensures its self-aggregation to form VFLS (either in the cytoplasm or nucleus) and recruitment of viral structural or nonstructural proteins.

Aquareovirus NS80 recruits viral proteins to its inclusions, and its C-terminal domain is the primary driving force for viral inclusion formation

Cytoplasmic inclusion bodies formed in reovirus-infected cells are the sites of viral replication and assembly. Previous studies have suggested that the NS80 protein of aquareovirus may be involved in the formation of viral inclusion bodies. However, it remains unknown whether other viral proteins are involved in the process, and what regions of NS80 may act coordinately in mediating inclusion formation. Here, we observed that globular cytoplasmic inclusions were formed in virus-infected cells and viral proteins NS80 and NS38 colocalized in the inclusions. During transfection, singly expressed NS80 could form cytoplasmic inclusions and recruit NS38 and GFP-tagged VP4 to these structures. Further treatment of cells with nocodazole, a microtubule inhibitor, did not disrupt the inclusion, suggesting that inclusion formation does not rely on microtubule network. Besides, we identified that the region 530–742 of NS80 was likely the minimal region required for inclusion formation, and the C-tail, coiled-coil region as well as the conserved linker region were essential for inclusion phenotype. Moreover, with series deletions from the N-terminus, a stepwise conversion occurred from large condensed cytoplasmic to small nuclear inclusions, then to a diffused intracellular distribution. Notablely, we found that the nuclear inclusions, formed by NS80 truncations (471 to 513–742), colocalized with cellular protein β-catenin. These data indicated that NS80 could be a major mediator in recruiting NS38 and VP4 into inclusion structures, and the C-terminus of NS80 is responsible for inclusion formation.

Avian and mammalian reoviruses use different molecular mechanisms to synthesize their {micro}NS isoforms

Previous reports revealed that the M3 gene of both avian and mammalian reoviruses express two isoforms of the non-structural protein μNS in infected cells. The larger isoforms initiate translation at the AUG codon closest to the 5' end of their respective m3 mRNAs, and were therefore designated μNS. In this study we have performed experiments to identify the molecular mechanisms by which the smaller μNS isoforms are generated. The results of this study confirmed the previous findings indicating that the smaller mammalian reovirus μNS isoform is a primary translation product, the translation of which is initiated at the internal AUG-41 codon of mammalian reovirus m3 mRNA. Our results further revealed that the smaller avian reovirus μNS isoform originates from a specific post-translational cleavage site near the amino terminus of μNS. This cleavage produces a 55 kDa carboxy-terminal protein, termed μNSC, and a 17 kDa amino-terminal polypeptide, designated μNSN. These results allowed us to extend the known avian reovirus protein-encoding capacity to 18 proteins, 12 of which are structural proteins and six of which are non-structural proteins. Our finding that avian and mammalian reoviruses use different mechanisms to express their μNSC isoforms suggests that these isoforms are important for reovirus replication.

A potentially novel reovirus isolated from swine in northeastern China in 2007

We report a novel reovirus (MRV-HLJ/2007) isolated from swine in Heilongjiang Province, China. Genome sequence analysis indicated a close genetic relationship between MRV-HLJ/2007 and strain SC-A, which was isolated from swine in 2006 in Sichuan, China. Although phylogenetic analysis indicated that MRV-HLJ/2007 may have originated from the SC-A strain, the M2 and S3 genes differ between these strains. Phylogenetic analysis also showed that, except for differences in the S1 gene, MRV-HLJ/2007 and SC-A are closely related to a reovirus that infects humans. These findings suggest that MRV-HLJ/2007 might be a novel reovirus strain circulating in China.

Broome virus, a new fusogenic Orthoreovirus species isolated from an Australian fruit bat

This report describes the discovery and characterization of a new fusogenic orthoreovirus, Broome virus (BroV), isolated from a little red flying-fox (Pteropus scapulatus). The BroV genome consists of 10 dsRNA segments, each having a 3' terminal pentanucleotide sequence conserved amongst all members of the genus Orthoreovirus, and a unique 5' terminal pentanucleotide sequence. The smallest genome segment is bicistronic and encodes two small nonstructural proteins, one of which is a novel fusion associated small transmembrane (FAST) protein responsible for syncytium formation, but no cell attachment protein. The low amino acid sequence identity between BroV proteins and those of other orthoreoviruses (13-50%), combined with phylogenetic analyses of structural and nonstructural proteins provide evidence to support the classification of BroV in a new sixth species group within the genus Orthoreovirus.

Mammalian reoviruses: propagation, quantification, and storage

Mammalian reoviruses are pathogens that cause gastrointestinal and respiratory infections. In humans, the mammalian reoviruses usually cause mild or subclinical disease, and they are ubiquitous, with most people mounting immunity at a young age. Reoviruses are prototypic representations of the Reoviridae family, which contains many highly pathogenic viruses. This unit describes techniques for culturing mouse fibroblast L929 cell lines, the preferred cell line in which most mammalian reovirus studies take place. In addition, mammalian reovirus propagation, quantification, purification, and storage are described.

Conserved structure/function of the orthoreovirus major core proteins

Orthoreoviruses are infectious agents with genomes of 10 segments of double-stranded RNA. Detailed molecular information is available for all 10 segments of several mammalian orthoreoviruses, and for most segments of several avian orthoreoviruses (ARV). We, and others, have reported sequences of the L2, all S-class, and all M-class genome segments of two different avian reoviruses, strains ARV138 and ARV176. We here determined L1 and L3 genome segment nucleotide sequences for both strains to complete full genome characterization of this orthoreovirus subgroup. ARV L1 segments were 3958 nucleotides long and encode lambda A major core shell proteins of 1293 residues. L3 segments were 3907 nucleotides long and encode lambda C core turret proteins of 1285 residues. These newly determined ARV segments were aligned with all currently available homologous mammalian reovirus (MRV) and aquareovirus (AqRV) genome segments. Identical and conserved amino acid residues amongst these diverse groups were mapped into known mammalian reovirus lambda 1 core shell and lambda 2 core turret proteins to predict conserved structure/function domains. Most identical and conserved residues were located near predicted catalytic domains in the lambda-class guanylyltransferase, and forming patches that traverse the lambda-class core shell, which may contribute to the unusual RNA transcription processes in this group of viruses.

Identification of functional domains in reovirus replication proteins muNS and mu2

Mammalian reoviruses are nonenveloped particles containing a genome of 10 double-stranded RNA (dsRNA) gene segments. Reovirus replication occurs within viral inclusions, which are specialized nonmembranous cytoplasmic organelles formed by viral nonstructural and structural proteins. Although these structures serve as sites for several major events in the reovirus life cycle, including dsRNA synthesis, gene segment assortment, and genome encapsidation, biochemical mechanisms of virion morphogenesis within inclusions have not been elucidated because much remains unknown about inclusion anatomy and functional organization. To better understand how inclusions support viral replication, we have used RNA interference (RNAi) and reverse genetics to define functional domains in two inclusion-associated proteins, muNS and mu2, which are interacting partners essential for inclusion development and viral replication. Removal of muNS N-terminal sequences required for association with mu2 or another muNS-binding protein, sigmaNS, prevented the capacity of muNS to support viral replication without affecting inclusion formation, indicating that muNS-mu2 and muNS-sigmaNS interactions are necessary for inclusion function but not establishment. In contrast, introduction of changes into the muNS C-terminal region, including sequences that form a putative oligomerization domain, precluded inclusion formation as well as viral replication. Mutational analysis of mu2 revealed a critical dependence of viral replication on an intact nucleotide/RNA triphosphatase domain and an N-terminal cluster of basic amino acid residues conforming to a nuclear localization motif. Another domain in mu2 governs the capacity of viral inclusions to affiliate with microtubules and thereby modulates inclusion morphology, either globular or filamentous. However, viral variants altered in inclusion morphology displayed equivalent replication efficiency. These studies reveal a modular functional organization of inclusion proteins muNS and mu2, define the importance of specific amino acid sequences and motifs in these proteins for viral replication, and demonstrate the utility of complementary RNAi-based and reverse genetic approaches for studies of reovirus replication proteins.

Avian reovirus L2 genome segment sequences and predicted structure/function of the encoded RNA-dependent RNA polymerase protein

Background

The orthoreoviruses are infectious agents that possess a genome comprised of 10 double-stranded RNA segments encased in two concentric protein capsids. Like virtually all RNA viruses, an RNA-dependent RNA polymerase (RdRp) enzyme is required for viral propagation. RdRp sequences have been determined for the prototype mammalian orthoreoviruses and for several other closely-related reoviruses, including aquareoviruses, but have not yet been reported for any avian orthoreoviruses.

Results

We determined the L2 genome segment nucleotide sequences, which encode the RdRp proteins, of two different avian reoviruses, strains ARV138 and ARV176 in order to define conserved and variable regions within reovirus RdRp proteins and to better delineate structure/function of this important enzyme. The ARV138 L2 genome segment was 3829 base pairs long, whereas the ARV176 L2 segment was 3830 nucleotides long. Both segments were predicted to encode λB RdRp proteins 1259 amino acids in length. Alignments of these newly-determined ARV genome segments, and their corresponding proteins, were performed with all currently available homologous mammalian reovirus (MRV) and aquareovirus (AqRV) genome segment and protein sequences. There was ~55% amino acid identity between ARV λB and MRV λ3 proteins, making the RdRp protein the most highly conserved of currently known orthoreovirus proteins, and there was ~28% identity between ARV λB and homologous MRV and AqRV RdRp proteins. Predictive structure/function mapping of identical and conserved residues within the known MRV λ3 atomic structure indicated most identical amino acids and conservative substitutions were located near and within predicted catalytic domains and lining RdRp channels, whereas non-identical amino acids were generally located on the molecule's surfaces.

Conclusion

The ARV λB and MRV λ3 proteins showed the highest ARV:MRV identity values (~55%) amongst all currently known ARV and MRV proteins. This implies significant evolutionary constraints are placed on dsRNA RdRp molecules, particularly in regions comprising the canonical polymerase motifs and residues thought to interact directly with template and nascent mRNA. This may point the way to improved design of anti-viral agents specifically targeting this enzyme.

Formation of the factory matrix is an important, though not a sufficient function of nonstructural protein mu NS during reovirus infection

Genome replication of mammalian orthoreovirus (MRV) occurs in cytoplasmic inclusion bodies called viral factories. Nonstructural protein microNS, encoded by genome segment M3, is a major constituent of these structures. When expressed without other viral proteins, microNS forms cytoplasmic inclusions morphologically similar to factories, suggesting a role for microNS as the factory framework or matrix. In addition, most other MRV proteins, including all five core proteins (lambda1, lambda2, lambda3, micro2, and sigma2) and nonstructural protein sigmaNS, can associate with microNS in these structures. In the current study, small interfering RNA targeting M3 was transfected in association with MRV infection and shown to cause a substantial reduction in microNS expression as well as, among other effects, a reduction in infectious yields by as much as 4 log(10) values. By also transfecting in vitro-transcribed M3 plus-strand RNA containing silent mutations that render it resistant to the small interfering RNA, we were able to complement microNS expression and to rescue infectious yields by ~100-fold. We next used microNS mutants specifically defective at forming factory-matrix structures to show that this function of microNS is important for MRV growth; point mutations in a C-proximal, putative zinc-hook motif as well as small deletions at the extreme C terminus of microNS prevented rescue of viral growth while causing microNS to be diffusely distributed in cells. We furthermore confirmed that an N-terminally truncated form of microNS, designed to represent microNSC and still able to form factory-matrix structures, is unable to rescue MRV growth, localizing one or more other important functions to an N-terminal region of microNS known to be involved in both micro2 and sigmaNS association. Thus, factory-matrix formation is an important, though not a sufficient function of microNS during MRV infection; microNS is multifunctional in the course of viral growth.

Avian reovirus core protein μA expressed in Escherichia coli possesses both NTPase and RTPase activities

Analysis of the amino acid sequence of core protein μA of avian reovirus has indicated that it may share similar functions to protein μ2 of mammalian reovirus. Since μ2 displayed both nucleotide triphosphatase (NTPase) and RNA triphosphatase (RTPase) activities, the purified recombinant μA ( μA) was designed and used to test these activities. μA was thus expressed in bacteria with a 4.5 kDa fusion peptide and six His tags at its N terminus. Results indicated that  μA possessed NTPase activity that enabled the protein to hydrolyse theβ–γphosphoanhydride bond of all four NTPs, since NDPs were the only radiolabelled products observed. The substrate preference was ATP>CTP>GTP>UTP, based on the estimatedkcatvalues. Alanine substitutions for lysines 408 and 412 (K408A/K412A) in a putative nucleotide-binding site of  μA abolished NTPase activity, further suggesting that NTPase activity is attributable to protein  μA. The activity of  μA is dependent on the divalent cations Mg2+or Mn2+, but not Ca2+or Zn2+. Optimal NTPase activity of  μA was achieved between pH 5.5 and 6.0. In addition,  μA enzymic activity increased with temperature up to 40 °C and was almost totally inhibited at temperatures higher than 55 °C. Tests of phosphate release from RNA substrates with  μA or K408A/K412A  μA indicated that  μA, but not K408A/K412A  μA, displayed RTPase activity. The results suggested that both NTPase and RTPase activities of  μA might be carried out at the same active site, and that protein μA could play important roles during viral RNA synthesis.

Characterization of M-class genome segments of muscovy duck reovirus S14

This report documents the first sequence analysis of the entire M1, M2, and M3 genome segments of the muscovy duck reovirus (DRV) S14. The complete sequence of each of the three M gene segments was determined. The M1 genome segment was 2283 nucleotides in length and was predicted to encode muA protein of 732 residues. The Escherichia coli expressed M1 transcripts generated a 108kDa protein, as expected for muA. A cleavage product of muA, muA1, could be detected by Western blotting with duck anti-reovirus and mouse anti-muA polyclonal serum. muA was distributed diffusely in the cytoplasma and nucleus of transfected Vero cells, which provides evidence that muA might be functional related to the mammalian reovirus (MRV) mu2. The M2 gene was 2155 nucleotides in length and was predicted to encode muB major outer capsid protein of 676 amino acids. The M3 genome segment was 1996 nucleotides in length and was predicted to encode a muNS protein of 635 amino acids. It was unexpectedly found that 5'-termini of the M1 and M2 genes ended with 5'-ACUUUU and 5'-UCUUUU, respectively, instead of 5'-GCUUUU, which is present on most mRNAs of other avian reoviruses (ARV). The UCAUC 3'-terminal sequences of the S14 M1, M2, and M3 genome segments are shared by DRV, ARV, and MRV. Alignment of the DRV muA-, muB-, and muNS-encoding genes with ARV revealed 72.9-73.9%, 67.1-69.6%, and 69.4-70.8% nucleotide identity, respectively. The amino acid sequence homology between DRV and ARV ranged from 85.3 to 86.2% (muA), 75.0 to 76.5% (muB), and 78.4 to 79.8% (muNS). Phylogenetic analyses of the M1, M2, M3, and S-class [Kuntz-Simon, G., Le Gall-Recule, G., de Boisseson, C., Jestin, V., 2002. Muscovy duck reovirus sigmaC protein is a typically encoded by the smallest genome segment. J. Gen. Virol. 83, 1189-1200; Zhang, Y., Liu, M., Hu, Q.L., Ouyang, S.D., Tong, G.Z., 2006a. Characterization of the sigmaC-encoding gene from muscovy duck reovirus. Virus Genes 36, 169-174; Zhang, Y., Liu, M., Ouyan, S.D., Hu, Q.L., Guo, D.C., Han, Z., 2006b. Detection and identification of avian, duck, and goose reoviruses by RT-PCR: goose and duck reoviruses aggregated the same specified genogroup in Orthoreovirus Genus II. Arch. Virol. 151, 1525-1538] genome segments suggests that DRV and ARV share a recent common ancestor and that the two lineages have subsequently undergone host dependent evolution.

Gene-specific inhibition of reovirus replication by RNA interference

Mammalian reoviruses contain a genome of 10 segments of double-stranded RNA (dsRNA). Reovirus replication and assembly occur within distinct structures called viral inclusions, which form in the cytoplasm of infected cells. Viral nonstructural proteins muNS and sigmaNS and core protein mu2 play key roles in forming viral inclusions and recruiting other viral proteins and RNA to these structures for replication and assembly. However, the precise functions of these proteins in viral replication are poorly defined. Therefore, to better understand the functions of reovirus proteins associated with formation of viral inclusions, we used plasmid-based vectors to establish 293T cell lines stably expressing small interfering RNAs (siRNAs) specific for transcripts encoding the mu2, muNS, and sigmaNS proteins of strain type 3 Dearing (T3D). Infectivity assays revealed that yields of T3D, but not those of strain type 1 Lang, were significantly decreased in 293T cells stably expressing mu2, muNS, or sigmaNS siRNA. Stable expression of siRNAs specific for any one of these proteins substantially diminished viral dsRNA, protein synthesis, and inclusion formation, indicating that each is a critical component of the viral replication machinery. Using cell lines stably expressing muNS siRNA, we developed a complementation system to rescue viral replication by transient transfection with recombinant T3D muNS in which silent mutations were introduced into the sequence targeted by the muNS siRNA. Furthermore, we demonstrated that muNSC, which lacks the first 40 amino residues of muNS, is incapable of restoring reovirus growth in the complementation system. These results reveal interdependent functions for viral inclusion proteins and indicate that cell lines stably expressing reovirus siRNAs are useful tools for the study of viral protein structure-function relationships.

Sequences of avian reovirus M1, M2 and M3 genes and predicted structure/function of the encoded mu proteins

We report the first sequence analysis of the entire complement of M-class genome segments of an avian reovirus (ARV). We analyzed the M1, M2 and M3 genome segment sequences, and sequences of the corresponding muA, muB and muNS proteins, of two virus strains, ARV138 and ARV176. The ARV M1 genes were 2,283 nucleotides in length and predicted to encode muA proteins of 732 residues. Alignment of the homologous mammalian reovirus (MRV) mu2 and ARV muA proteins revealed a relatively low overall amino acid identity ( approximately 30%), although several highly conserved regions were identified that may contribute to conserved structural and/or functional properties of this minor core protein (i.e. the MRV mu2 protein is an NTPase and a putative RNA-dependent RNA polymerase cofactor). The ARV M2 genes were 2158 nucleotides in length, encoding predicted muB major outer capsid proteins of 676 amino acids, more than 30 amino acids shorter than the homologous MRV mu1 proteins. In spite of the difference in size, the ARV/MRV muB/mu1 proteins were more conserved than any of the homologous proteins encoded by other M- or S-class genome segments, exhibiting percent amino acid identities of approximately 45%. The conserved regions included the residues involved in the maturation- and entry- specific proteolytic cleavages that occur in the MRV mu1 protein. Notably missing was a region recently implicated in MRV mu1 stabilization and in forming "hub and spokes" complexes in the MRV outer capsid. The ARV M3 genes were 1996 nucleotides in length and predicted to encode a muNS non-structural protein of 635 amino acids, significantly shorter than the homologous MRV muNS protein, which is attributed to several substantial deletions in the aligned ARV muNS proteins. Alignments of the ARV and MRV muNS proteins revealed a low overall amino acid identity ( approximately 25%), although several regions were relatively conserved.

The sequence and phylogenetic analysis of avian reovirus genome segments M1, M2, and M3 encoding the minor core protein muA, the major outer capsid protein muB, and the nonstructural protein muNS

The sequences and phylogenetic analyses of the M-class genome segments of 12 avian reovirus strains are described. The S1133 M1 genome segment is 2283 base pairs long, encoding a protein muA consisted of 732 amino acids. Each M2 or M3 genome segment of 12 avian reovirus strains is 2158 or 1996 base pairs long, respectively, encoding a protein muB or muNS consisted of 676 and 635 amino acids, respectively. The S1133 genome segment has the 5' GCUUUU terminal motif, but each M2 and M3 genome segment displays the 5' GCUUUUU terminal motif which is common to other known avian reovirus genome segments. The UCAUC 3'-terminal sequences of the M-class genome segments are shared by both avian and mammalian reoviruses. Noncoding regions of both 5'- and 3'-termini of the S1133 M1 genome segment consist of 12 and 72 nucleotides, respectively, those of each M2 genome segment consist of 29 and 98 nucleotides, respectively, and those of each M3 genome segment are 24 and 64 nucleotides, respectively. Analysis of the average degree of the M-class gene and the deduced mu-class protein sequence identities indicated that the M2 genes and the muB proteins have the greatest level of sequence divergence. Computer searches revealed that the muA possesses a sequence motif (NH(2)-Leu-Ala-Leu-Asp-Pro-Pro-Phe-COOH) (residues 458-464) indicative of N-6 adenine-specific DNA methylase. Examination of the muB amino acid sequences indicated that the cleavage site of muB into muBN and muBC is between positions 42 and 43 near the N-terminus of the protein, and this site is conserved for each protein. During in vitro treatment of virions with trypsin to yield infectious subviral particles, both the N-terminal fragment delta and the C-terminal fragment phi were shown to be generated. The site of trypsin cleavage was identified in the deduced amino acid sequence of muB by determining the amino-terminal sequences of phi proteins: between arginine 582 and glycine 583. The predicted length of delta generated from muBC is very similar to that of delta generated from mammalian reovirus mu1C. Taken together, protein muB is structurally, and probably functionally, similar to its mammalian homolog, mu1. In addition, two regions near the C-terminal and with a propensity to form alpha-helical coiled-coil structures as previously indicated are observed for each protein muB. Phylogenetic analysis of the M-class genes revealed that the predicted phylograms delineated 3 M1, 5 M2, and 2 M3 lineages, no correlation with serotype or pathotype of the viruses. The results also showed that M2 lineages I-V consist of a mixture of viruses from the M1 and M3 genes of lineages I-III, reflecting frequent reassortment of these genes among virus strains.

Carboxyl-proximal regions of reovirus nonstructural protein muNS necessary and sufficient for forming factory-like inclusions

Mammalian orthoreoviruses are believed to replicate in distinctive, cytoplasmic inclusion bodies, commonly called viral factories or viroplasms. The viral nonstructural protein muNS has been implicated in forming the matrix of these structures, as well as in recruiting other components to them for putative roles in genome replication and particle assembly. In this study, we sought to identify the regions of muNS that are involved in forming factory-like inclusions in transfected cells in the absence of infection or other viral proteins. Sequences in the carboxyl-terminal one-third of the 721-residue muNS protein were linked to this activity. Deletion of as few as eight residues from the carboxyl terminus of muNS resulted in loss of inclusion formation, suggesting that some portion of these residues is required for the phenotype. A region spanning residues 471 to 721 of muNS was the smallest one shown to be sufficient for forming factory-like inclusions. The region from positions 471 to 721 (471-721 region) includes both of two previously predicted coiled-coil segments in muNS, suggesting that one or both of these segments may also be required for inclusion formation. Deletion of the more amino-terminal one of the two predicted coiled-coil segments from the 471-721 region resulted in loss of the phenotype, although replacement of this segment with Aequorea victoria green fluorescent protein, which is known to weakly dimerize, largely restored inclusion formation. Sequences between the two predicted coiled-coil segments were also required for forming factory-like inclusions, and mutation of either one His residue (His570) or one Cys residue (Cys572) within these sequences disrupted the phenotype. The His and Cys residues are part of a small consensus motif that is conserved across muNS homologs from avian orthoreoviruses and aquareoviruses, suggesting this motif may have a common function in these related viruses. The inclusion-forming 471-721 region of muNS was shown to provide a useful platform for the presentation of peptides for studies of protein-protein association through colocalization to factory-like inclusions in transfected cells.

Putative autocleavage of reovirus mu1 protein in concert with outer-capsid disassembly and activation for membrane permeabilization

Capsid proteins of several different families of non-enveloped animal viruses with single-stranded RNA genomes undergo autocatalytic cleavage (autocleavage) as a maturation step in assembly. Similarly, the 76 kDa major outer-capsid protein mu1 of mammalian orthoreoviruses (reoviruses), which are non-enveloped and have double-stranded RNA genomes, undergoes putative autocleavage between residues 42 and 43, yielding N-terminal N-myristoylated fragment mu1N and C-terminal fragment mu1C. Cleavage at this site allows release of mu1N, which is thought to be critical for penetration of the host-cell membrane during cell entry. Most previous studies have suggested that cleavage at the mu1N/mu1C junction precedes addition to the outer capsid during virion assembly, such that only a small number of the mu1 subunits in mature virions remain uncleaved at that site (approximately 5%). In this study, we varied the conditions for disruption of virions before running the proteins on denaturing gels and in several circumstances recovered much higher levels of uncleaved mu1 (up to approximately 60%). Elements of the disruption conditions that allowed greater recovery of uncleaved protein were increased pH, absence of reducing agent, and decreased temperature. These same elements allowed comparably higher levels of the mu1delta protein, in which cleavage at the mu1N/delta junction has not occurred, to be recovered from particle uncoating intermediates in which mu1 had been previously cleaved by chymotrypsin in a distinct protease-sensitive region near residue 580. The capacity to recover higher levels of mu1delta following disruption of these particles for electrophoresis was lost, however, in concert with a series of structural changes that activate the particles for membrane permeabilization, suggesting that the putative autocleavage is itself one of these changes.

Comparisons of the M1 genome segments and encoded mu2 proteins of different reovirus isolates

Background

The reovirus M1 genome segment encodes the μ2 protein, a structurally minor component of the viral core, which has been identified as a transcriptase cofactor, nucleoside and RNA triphosphatase, and microtubule-binding protein. The μ2 protein is the most poorly understood of the reovirus structural proteins. Genome segment sequences have been reported for 9 of the 10 genome segments for the 3 prototypic reoviruses type 1 Lang (T1L), type 2 Jones (T2J), and type 3 Dearing (T3D), but the M1 genome segment sequences for only T1L and T3D have been previously reported. For this study, we determined the M1 nucleotide and deduced μ2 amino acid sequences for T2J, nine other reovirus field isolates, and various T3D plaque-isolated clones from different laboratories.

Results

Determination of the T2J M1 sequence completes the analysis of all ten genome segments of that prototype. The T2J M1 sequence contained a 1 base pair deletion in the 3' non-translated region, compared to the T1L and T3D M1 sequences. The T2J M1 gene showed ~80% nucleotide homology, and the encoded μ2 protein showed ~71% amino acid identity, with the T1L and T3D M1 and μ2 sequences, respectively, making the T2J M1 gene and μ2 proteins amongst the most divergent of all reovirus genes and proteins. Comparisons of these newly determined M1 and μ2 sequences with newly determined M1 and μ2 sequences from nine additional field isolates and a variety of laboratory T3D clones identified conserved features and/or regions that provide clues about μ2 structure and function.

Conclusions

The findings suggest a model for the domain organization of μ2 and provide further evidence for a role of μ2 in viral RNA synthesis. The new sequences were also used to explore the basis for M1/μ2-determined differences in the morphology of viral factories in infected cells. The findings confirm the key role of Ser/Pro208 as a prevalent determinant of differences in factory morphology among reovirus isolates and trace the divergence of this residue and its associated phenotype among the different laboratory-specific clones of type 3 Dearing.

Inhibition of reovirus by mycophenolic acid is associated with the M1 genome segment

Mycophenolic acid (MPA), an inhibitor of IMP dehydrogenase, inhibits reovirus replication and viral RNA and protein production. In mouse L929 cells, antiviral effects were greatest at 30 microg of MPA/ml. At this dosage, MPA inhibited replication of reovirus strain T3D more than 1,000-fold and inhibited replication of reovirus strain T1L nearly 100-fold, compared to non-drug-treated controls. Genetic reassortant analysis indicated the primary determinant of strain-specific differences in sensitivity to MPA mapped to the viral M1 genome segment, which encodes the minor core protein mu2. MPA also inhibited replication of both strains of reovirus in a variety of other cell lines, including Vero monkey kidney and U373 human astrocytoma cells. Addition of exogenous guanosine to MPA-treated reovirus-infected cells restored viral replicative capacity to nearly normal levels. These results suggest the mu2 protein is involved in the uptake and processing of GTP in viral transcription in infected cells and strengthens the evidence that the mu2 protein can function as an NTPase and is likely a transcriptase cofactor.

Avian reovirus nonstructural protein microNS forms viroplasm-like inclusions and recruits protein sigmaNS to these structures

The M3 genome segment of avian reovirus 1733, which encodes the nonstructural protein microNS, is 1996 nucleotides long and contains a long open reading frame that is predicted to encode a polypeptide of 635 amino acid residues. Examination of the deduced amino acid sequence of microNS revealed the presence of two regions near its carboxyl terminus with a high probability of forming alpha-helical coiled coils. Expression of the M3 gene in both infected and transfected cells revealed that this gene specifies two protein isoforms that are recognized by a microNS-specific antiserum. Only the larger microNS isoform, but not the smaller one, interacts with the nonstructural protein sigmaNS in infected cells, suggesting that the two isoforms play different roles during avian reovirus infection. In the second part of this study, we show that microNS and the nonstructural protein sigmaNS colocalize throughout the viral life cycle in large and small phase-dense globular cytoplasmic inclusions, which are believed to be the sites of viral replication and assembly. Individual expression of these proteins in transfected cells of avian and mammalian origin revealed that while microNS is able to form inclusions in the absence of other viral proteins, sigmaNS distributes diffusely throughout the cytoplasm in the absence of microNS. These data suggest that microNS is the minimal viral factor required for inclusion formation during avian reovirus infection. On the other hand, our findings that sigmaNS associates with microNS in infected cells, and that sigmaNS colocalizes with microNS in viroplasm-like inclusions when the two proteins are coexpressed in transfected cells, suggest that microNS mediates the association of sigmaNS to inclusions in avian reovirus-infected cells.

Reovirus nonstructural protein mu NS recruits viral core surface proteins and entering core particles to factory-like inclusions

Mammalian reoviruses are thought to assemble and replicate within cytoplasmic, nonmembranous structures called viral factories. The viral nonstructural protein mu NS forms factory-like globular inclusions when expressed in the absence of other viral proteins and binds to the surfaces of the viral core particles in vitro. Given these previous observations, we hypothesized that one or more of the core surface proteins may be recruited to viral factories through specific associations with mu NS. We found that all three of these proteins--lambda 1, lambda 2, and sigma 2--localized to factories in infected cells but were diffusely distributed through the cytoplasm and nucleus when each was separately expressed in the absence of other viral proteins. When separately coexpressed with mu NS, on the other hand, each core surface protein colocalized with mu NS in globular inclusions, supporting the initial hypothesis. We also found that lambda 1, lambda 2, and sigma 2 each localized to filamentous inclusions formed upon the coexpression of mu NS and mu 2, a structurally minor core protein that associates with microtubules. The first 40 residues of mu NS, which are required for association with mu 2 and the RNA-binding nonstructural protein sigma NS, were not required for association with any of the three core surface proteins. When coexpressed with mu 2 in the absence of mu NS, each of the core surface proteins was diffusely distributed and displayed only sporadic, weak associations with mu 2 on filaments. Many of the core particles that entered the cytoplasm of cycloheximide-treated cells following entry and partial uncoating were recruited to inclusions of mu NS that had been preformed in those cells, providing evidence that mu NS can bind to the surfaces of cores in vivo. These findings expand a model for how viral and cellular components are recruited to the viral factories in infected cells and provide further evidence for the central but distinct roles of viral proteins mu NS and mu 2 in this process.

Cathepsin S supports acid-independent infection by some reoviruses

In murine fibroblasts, efficient proteolysis of reovirus outer capsid protein sigma3 during cell entry by virions requires the acid-dependent lysosomal cysteine protease cathepsin L. The importance of cathepsin L for infection of other cell types is unknown. Here we report that the acid-independent lysosomal cysteine protease cathepsin S mediates outer capsid processing in macrophage-like P388D cells. P388D cells supported infection by virions of strain Lang, but not strain c43. Genetic studies revealed that this difference is determined by S4, the viral gene segment that encodes sigma3. c43-derived subvirion particles that lack sigma3 replicated normally in P388D cells, suggesting that the difference in infectivity of Lang and c43 virions is at the level of sigma3 processing. Infection of P388D cells with Lang virions was inhibited by the broad spectrum cysteine protease inhibitor trans-epoxysuccinyl-l-leucylamido-(4-guanidino)butane but not by NH(4)Cl, which raises the endocytic pH and thereby inhibits acid-dependent proteases such as cathepsins L and B. Outer capsid processing and infection of P388D cells with Lang virions were also inhibited by a cathepsin S-specific inhibitor. Furthermore, in the presence of NH(4)Cl, cell lines engineered to express cathepsin S supported infection by Lang, but not c43, virions. Our results thus indicate that differences in susceptibility to cathepsin S-mediated sigma3 processing are responsible for strain differences in reovirus infection of macrophage-like P388D cells and other cathepsin S-expressing cells. Additionally, our data suggest that the acid dependence of reovirus infections of most other cell types may reflect the low pH requirement for the activities of most other lysosomal proteases rather, than some other acid-dependent aspect of cell entry.

Nucleoside and RNA triphosphatase activities of orthoreovirus transcriptase cofactor mu2

The mammalian Orthoreovirus (mORV) core particle is an icosahedral multienzyme complex for viral mRNA synthesis and provides a delimited system for mechanistic studies of that process. Previous genetic results have identified the mORV mu2 protein as a determinant of viral strain differences in the transcriptase and nucleoside triphosphatase activities of cores. New results in this report provided biochemical and genetic evidence that purified mu2 is itself a divalent cation-dependent nucleoside triphosphatase that can remove the 5' gamma-phosphate from RNA as well. Alanine substitutions in a putative nucleotide binding region of mu2 abrogated both functions but did not affect the purification profile of the protein or its known associations with microtubules and mORV microNS protein in vivo. In vitro microtubule binding by purified mu2 was also demonstrated and not affected by the mutations. Purified mu2 was further demonstrated to interact in vitro with the mORV RNA-dependent RNA polymerase, lambda3, and the presence of lambda3 mildly stimulated the triphosphatase activities of mu2. These findings confirm that mu2 is an enzymatic component of the mORV core and may contribute several possible functions to viral mRNA synthesis.

Reovirus sigma NS protein localizes to inclusions through an association requiring the mu NS amino terminus

Cells infected with mammalian reoviruses contain phase-dense inclusions, called viral factories, in which viral replication and assembly are thought to occur. The major reovirus nonstructural protein mu NS forms morphologically similar phase-dense inclusions when expressed in the absence of other viral proteins, suggesting it is a primary determinant of factory formation. In this study we examined the localization of the other major reovirus nonstructural protein, sigma NS. Although sigma NS colocalized with mu NS in viral factories during infection, it was distributed diffusely throughout the cell when expressed in the absence of mu NS. When coexpressed with mu NS, sigma NS was redistributed and colocalized with mu NS inclusions, indicating that the two proteins associate in the absence of other viral proteins and suggesting that this association may mediate the localization of sigma NS to viral factories in infected cells. We have previously shown that mu NS residues 1 to 40 or 41 are both necessary and sufficient for mu NS association with the viral microtubule-associated protein mu 2. In the present study we found that this same region of micro NS is required for its association with sigma NS. We further dissected this region, identifying residues 1 to 13 of mu NS as necessary for association with sigma NS, but not with mu 2. Deletion of sigma NS residues 1 to 11, which we have previously shown to be required for RNA binding by that protein, resulted in diminished association of sigma NS with mu NS. Furthermore, when treated with RNase, a large portion of sigma NS was released from mu NS coimmunoprecipitates, suggesting that RNA contributes to their association. The results of this study provide further evidence that mu NS plays a key role in forming the reovirus factories and recruiting other components to them.

Mammalian reovirus nonstructural protein microNS forms large inclusions and colocalizes with reovirus microtubule-associated protein micro2 in transfected cells

Cells infected with mammalian orthoreoviruses contain large cytoplasmic phase-dense inclusions believed to be the sites of viral replication and assembly, but the morphogenesis, structure, and specific functions of these "viral factories" are poorly understood. Using immunofluorescence microscopy, we found that reovirus nonstructural protein microNS expressed in transfected cells forms inclusions that resemble the globular viral factories formed in cells infected with reovirus strain type 3 Dearing from our laboratory (T3D(N)). In the transfected cells, the formation of microNS large globular perinuclear inclusions was dependent on the microtubule network, as demonstrated by the appearance of many smaller microNS globular inclusions dispersed throughout the cytoplasm after treatment with the microtubule-depolymerizing drug nocodazole. Coexpression of microNS and reovirus protein micro2 from a different strain, type 1 Lang (T1L), which forms filamentous viral factories, altered the distributions of both proteins. In cotransfected cells, the two proteins colocalized in thick filamentous structures. After nocodazole treatment, many small dispersed globular inclusions containing microNS and micro2 were seen, demonstrating that the microtubule network is required for the formation of the filamentous structures. When coexpressed, the micro2 protein from T3D(N) also colocalized with microNS, but in globular inclusions rather than filamentous structures. The morphology difference between the globular inclusions containing microNS and micro2 protein from T3D(N) and the filamentous structures containing microNS and micro2 protein from T1L in cotransfected cells mimicked the morphology difference between globular and filamentous factories in reovirus-infected cells, which is determined by the micro2-encoding M1 genome segment. We found that the first 40 amino acids of microNS are required for colocalization with micro2 but not for inclusion formation. Similarly, a fusion of microNS amino acids 1 to 41 to green fluorescent protein was sufficient for colocalization with the micro2 protein from T1L but not for inclusion formation. These observations suggest a functional difference between microNS and microNSC, a smaller form of the protein that is present in infected cells and that is missing amino acids from the amino terminus of microNS. The capacity of microNS to form inclusions and to colocalize with micro2 in transfected cells suggests a key role for microNS in forming viral factories in reovirus-infected cells.

Reovirus core protein mu2 determines the filamentous morphology of viral inclusion bodies by interacting with and stabilizing microtubules

Cells infected with mammalian reoviruses often contain large perinuclear inclusion bodies, or "factories," where viral replication and assembly are thought to occur. Here, we report a viral strain difference in the morphology of these inclusions: filamentous inclusions formed in cells infected with reovirus type 1 Lang (T1L), whereas globular inclusions formed in cells infected with our laboratory's isolate of reovirus type 3 Dearing (T3D). Examination by immunofluorescence microscopy revealed the filamentous inclusions to be colinear with microtubules (MTs). The filamentous distribution was dependent on an intact MT network, as depolymerization of MTs early after infection caused globular inclusions to form. The inclusion phenotypes of T1L x T3D reassortant viruses identified the viral M1 genome segment as the primary genetic determinant of the strain difference in inclusion morphology. Filamentous inclusions were seen with 21 of 22 other reovirus strains, including an isolate of T3D obtained from another laboratory. When the mu2 proteins derived from T1L and the other laboratory's T3D isolate were expressed after transfection of their cloned M1 genes, they associated with filamentous structures that colocalized with MTs, whereas the mu2 protein derived from our laboratory's T3D isolate did not. MTs were stabilized in cells infected with the viruses that induced filamentous inclusions and after transfection with the M1 genes derived from those viruses. Evidence for MT stabilization included bundling and hyperacetylation of alpha-tubulin, changes characteristically seen when MT-associated proteins (MAPs) are overexpressed. Sequencing of the M1 segments from the different T1L and T3D isolates revealed that a single-amino-acid difference at position 208 correlated with the inclusion morphology. Two mutant forms of mu2 with the changes Pro-208 to Ser in a background of T1L mu2 and Ser-208 to Pro in a background of T3D mu2 had MT association phenotypes opposite to those of the respective wild-type proteins. We conclude that the mu2 protein of most reovirus strains is a viral MAP and that it plays a key role in the formation and structural organization of reovirus inclusion bodies.

Mammalian reovirus core protein micro 2 initiates at the first start codon and is acetylated

Mammalian reovirus is an enteric virus that contains a double-stranded RNA genome. The genome consists of ten RNA segments that encode eight structural and three non-structural proteins. The structural proteins form a double-layered structure. The innermost layer, called the core, consists of five proteins (lambda1, lambda2, lambda3, micro 2, and sigma2). Protein lambda3 is the RNA-dependent RNA polymerase (RdRp) and micro 2 is thought to be an RdRp cofactor. Translation of most reovirus proteins is known to commence at the first start codon. However, the translation initiation site of the viral core protein micro 2, encoded by the M1 RNA segment, has been in dispute. Although the theoretical molecular weight of micro 2 is 83 267 Da the actual molecular weight is unknown because micro 2 runs aberrantly in SDS-PAGE and has resisted characterization by Edman degradation, indicating that the amino terminus is post-translationally modified. In this study, we used proteolysis coupled with MALDI-Qq-TOFMS to determine that translation of micro 2 initiates at the first AUG codon, that its actual molecular weight approximates the theoretical value of 83 kDa, that the amino terminal methionine residue is removed, and that the next amino acid (alanine) is post-translationally acetylated.

Reovirus mu2 protein determines strain-specific differences in the rate of viral inclusion formation in L929 cells

Reovirus infection induces the formation of large cytoplasmic inclusions that serve as the major site of viral assembly. Reovirus strains type 3 Dearing (T3D) and type 1 Lang (T1L) differ in the rate of inclusion formation in L929 cells. The median time of inclusion formation is 18 h in cells infected with T3D and 39 h in cells infected with T1L. Using reassortant viruses that contain combinations of gene segments derived from T1L and T3D, we found that the M1 gene, which encodes the mu2 protein, is the primary determinant of the rate of inclusion formation. The S3 gene, which encodes the nonstructural protein sigmaNS, plays a secondary role in this process. The subcellular location of the mu2 protein was determined by confocal laser scanning microscopy using dual-fluorescence labeling of mu2 and the outer-capsid protein mu1/mu1C. In virus-infected cells, mu2 protein colocalized with other viral proteins in inclusions and was also distributed diffusely in the cytoplasm and nucleus. Expression of recombinant T1L and T3D mu2 proteins resulted in the formation of protein complexes resembling inclusions in both the cytoplasm and the nucleus with kinetics that reflected the strain of origin. The median time of mu2 protein complex formation was 22 h in cells transfected with the T3D M1 gene and 43 h in cells transfected with the T1L M1 gene. These findings suggest that the mu2 protein influences the rate of inclusion formation and contributes to inclusion morphogenesis. The requirement of mu2 protein in inclusion formation was tested by determining the subcellular localization of mu2 in cells infected with temperature-sensitive (ts) mutants that are defective in viral assembly. In contrast to infection with wild-type virus, mu2 did not colocalize with mu1/mu1C protein in subcellular structures that formed in cells infected at nonpermissive temperature with ts mutants tsH11.2, tsC447, and tsG453 with mutations in the M1, S2, and S4 genes, respectively. These results suggest that despite the role of the mu2 protein in controlling the rate of inclusion formation, this process is a concerted function of several reovirus proteins.

Reovirus nonstructural protein muNS binds to core particles but does not inhibit their transcription and capping activities

Previous studies provided evidence that nonstructural protein muNS of mammalian reoviruses is present in particle assembly intermediates isolated from infected cells. Morgan and Zweerink (Virology 68:455-466, 1975) showed that a subset of these intermediates, which can synthesize the viral plus strand RNA transcripts in vitro, comprise core-like particles plus large amounts of muNS. Given the possible role of muNS in particle assembly and/or transcription implied by those findings, we tested whether recombinant muNS can bind to cores in vitro. The muNS protein bound to cores, but not to two particle forms, virions and intermediate subvirion particles, that contain additional outer-capsid proteins. Incubating cores with increasing amounts of muNS resulted in particle complexes of progressively decreasing buoyant density, approaching the density of protein alone when very large amounts of muNS were bound. Thus, the muNS-core interaction did not exhibit saturation or a defined stoichiometry. Negative-stain electron microscopy of the muNS-bound cores revealed that the cores were intact and linked together in large complexes by an amorphous density, which we ascribe to muNS. The muNS-core complexes retained the capacity to synthesize the viral plus strand transcripts as well as the capacity to add methylated caps to the 5' ends of the transcripts. In vitro competition assays showed that mixing muNS with cores greatly reduced the formation of recoated cores by stoichiometric binding of outer-capsid proteins mu1 and sigma3. These findings are consistent with the presence of muNS in transcriptase particles as described previously and suggest that, by binding to cores in the infected cell, muNS may block or delay outer-capsid assembly and allow continued transcription by these particles.

Mammalian reovirus M3 gene sequences and conservation of coiled-coil motifs near the carboxyl terminus of the microNS protein

Nucleotide sequences of the mammalian orthoreovirus (reovirus) type 1 Lang and type 2 Jones M3 gene segments were newly determined. The nucleotide sequence of the reovirus type 3 Dearing M3 segment also was determined to compare with a previously reported M3 sequence for that isolate. Comparisons showed Lang and Dearing M3 to be more closely related than either was to Jones M3, consistent with previous findings for other reovirus gene segments. The microNS protein sequences deduced from each M3 segment were shown to be related in a similar pattern as the respective nucleotide sequences and to contain several regions of greater or less than average variability among the three isolates. Identification of conserved methionine codons near the 5' ends of the Lang, Jones, and Dearing M3 plus strands lent support to the hypothesis that microNSC, a smaller protein also encoded by M3, arises by translation initiation from a downstream methionine codon within the same open reading frame as microNS. Other analyses of the deduced protein sequences indicated that regions within the carboxyl-terminal third of microNS and microNSC from each isolate have a propensity to form alpha-helical coiled coils, most likely coiled-coil dimers. The new sequences will augment further studies on microNS and microNSC structure and function.

Mammalian reovirus L3 gene sequences and evidence for a distinct amino-terminal region of the lambda1 protein

To complement evidence for nucleoside triphosphate phosphohydrolase (NTPase), RNA helicase, RNA 5' triphosphate phosphohydrolase, and nucleic acid-binding activities by the core shell protein lambda1 of mammalian orthoreoviruses (reoviruses), we determined nucleotide sequences of the lambda1-encoding L3 gene segments from three isolates: type 1 Lang (T1L), type 2 Jones (T2J), and type 3 Dearing (T3D). The T1L and T3D L3 gene sequences and deduced lambda1 protein sequences shared high levels of identity (97.7% and 99.3%, respectively). The lambda1 sequences differed at only 9 of 1275 amino acids. Two single-nucleotide insertions relative to a previously published sequence for T3D L3 extended the lambda1 open reading frame to within 60 nucleotides of the plus-strand 3' end for T3D and the other isolates sequenced, in keeping with the short 3' nontranslated regions of the other nine gene segments. Seven of the nine amino acid differences between T1L and T3D lambda1 were located within the amino-terminal 500 residues of lambda1, a region with putative sequence similarities to NTPases and RNA helicases. The T2J L3 and lambda1 sequences were found to be more divergent, especially within the amino-terminal 180 residues of lambda1, preceding the putative CCHH zinc finger motif. The T2J L3 sequence, along with partial sequences for L3 genes from three other reovirus isolates, suggested that one or more of the polymorphisms at amino acids 71, 215, 500, 1011, and/or 1100 in lambda1 contribute to the L3-determined differences in ATPase activities by T1L and T3D cores. The findings contribute to our ongoing efforts to elucidate sequence-structure-function relationships for the lambda1 core protein.

The reovirus mutant tsA279 L2 gene is associated with generation of a spikeless core particle: implications for capsid assembly

Previous studies which used intertypic reassortants of the wild-type reovirus serotype 1 Lang and the temperature-sensitive (ts) serotype 3 mutant clone tsA279 identified two ts lesions; one lesion, in the M2 gene segment, was associated with defective transmembrane transport of restrictively assembled virions (P. R. Hazelton and K. M. Coombs, Virology 207:46-58, 1995). In the present study we show that the second lesion, in the L2 gene segment, which encodes the lambda2 protein, is associated with the accumulation of a core-like particle defective for the lambda2 pentameric spike. Physicochemical, biochemical, and immunological studies showed that these structures were deficient for genomic double-stranded RNA, the core spike protein lambda2, and the minor core protein micro2. Core particles with the lambda2 spike structure accumulated after temperature shift-down from a restrictive to a permissive temperature in the presence of cycloheximide. These data suggest the spike-deficient, core-like particle is an assembly intermediate in reovirus morphogenesis. The existence of this naturally occurring primary core structure suggests that the core proteins lambda1, lambda3, and sigma2 interact to initiate the process of virion capsid assembly through a dodecahedral mechanism. The next step in the proposed capsid assembly model would be the association of the minor core protein mu2, either preceding or collateral to the condensation of the lambda2 pentameric spike at the apices of the primary core structure. The assembly pathway of the reovirus double capsid is further elaborated when these observations are combined with structures identified in other studies.

The reovirus protein mu2, encoded by the M1 gene, is an RNA-binding protein

The reovirus M1, L1, and L2 genes encode proteins found at each vertex of the viral core and are likely to form a structural unit involved in RNA synthesis. Genetic analyses have implicated the M1 gene in viral RNA synthesis and core nucleoside triphosphatase activity, but there have been no direct biochemical studies of mu2 function. Here, we expressed mu2 in vitro and assessed its RNA-binding activity. The expressed mu2 binds both poly(I-C)- and poly(U)-Sepharose, and binding activity is greater in Mn2+ than in Mg2+. Heterologous RNA competes for mu2 binding to reovirus RNA transcripts as effectively as homologous reovirus RNA does, providing no evidence for sequence-specific RNA binding by mu2. Protein mu2 is now the sixth reovirus protein demonstrated to have RNA-binding activity.

Nucleotide sequence of Bombyx mori cytoplasmic polyhedrosis virus segment 8

The segments 8 (S8) of the 10 double-stranded RNA genomes from Bombyx mori cytoplasmic polyhedrosis virus (BmCPV) strains I and H were converted into cDNAs, amplified by PCR, and cloned. The nucleotide sequence analysis of the two full-length S8 cDNAs showed that the segments consist of 1328 nucleotides encoding putative proteins (p44) of 390 amino acids with molecular masses of about 44 kDa, which have glutamic acid-rich and proline-rich domains in their central regions. They had quite high identity with each other: about 98% in nucleotide and amino acid sequences. The recombinant p44 expressed in BmN4 cells using the baculovirus vector was detected by immunoblot analysis. p44 was also confirmed with the same antiserum to be present in BmCPV-infected midgut cells, but not in polyhedra, virus virions and uninfected midgut cells, indicating that p44 is expressed as a nonstructural protein of BmCPV.

Core protein mu2 is a second determinant of nucleoside triphosphatase activities by reovirus cores

NTPase activities in mammalian reovirus cores were examined under various conditions that permitted several new differences to be identified between strains type 1 Lang (T1L) and type 3 Dearing (T3D). One difference concerned the ratio (at pH 8.5) of ATP hydrolysis at 50 degrees C to that at 35 degrees C. A genetic analysis using T1L x T3D reassortant viruses implicated the L3 and M1 gene segments in this difference, with M1 influencing ATPase activity most strongly at high temperatures. L3 and M1 encode the core proteins lambda1 and mu2, respectively. Another difference concerned the absolute levels of GTP hydrolysis by cores at 45 degrees C and pH 6.5. A genetic analysis using T1L x T3D reassortants implicated the M1 gene as the sole determinant of this difference. The results of these experiments, coupled with previous findings (S. Noble and M. L. Nibert, J. Virol. 71:2182-2191, 1997), suggest either that a single type of NTPase in cores is strongly influenced by two different core proteins--lambda1 and mu2--or that cores contain two different types of NTPase influenced by the two proteins. The findings appear relevant for understanding the complex functions of reovirus cores in RNA synthesis and capping.

Identification and characterization of a double-stranded RNA- reovirus temperature-sensitive mutant defective in minor core protein mu2

A newly identified temperature-sensitive mutant whose defect was mapped to the reovirus M1 gene (minor core protein mu2) was studied to better understand the functions of this virion protein. Sequence determination of the Ml gene of this mutant (tsH11.2) revealed a predicted methionine-to-threonine alteration at amino acid 399 and a change from proline to histidine at amino acid 414. The mutant made normal amounts of single-stranded RNA, both in in vitro transcriptase assays and in infected cells, and normal amounts of progeny viral protein at early times in a restrictive infection. However, tsH11.2 produced neither detectable progeny protein nor double-stranded RNA at late times in a restrictive infection. These studies indicate that mu2 plays a role in the conversion of reovirus mRNA to progeny double-stranded RNA.

The M1 gene is associated with differences in the temperature optimum of the transcriptase activity in reovirus core particles

The reovirus core is a multienzyme complex that contains five different structural proteins and 10 segments of double-stranded RNA. The core is responsible for transcribing mRNA from the enclosed double-stranded RNA. The reovirus transcriptase has an unusual temperature profile, with optimum transcription occurring at approximately 50 degrees C and little activity occurring below 30 or above 60 degrees C. Purified reovirus serotype 1 Lang (T1L) cores transcribed most efficiently at 48 degrees C. The transcriptase temperature optimum of purified reovirus serotype 3 Dearing (T3D) cores was 52 degrees C. In addition, T1L cores produced more mRNA per particle than did T3D cores at their respective temperature optima. Core particles were purified from T1L x T3D reassortants and were used to map these differences. The M1 gene, which encodes minor core protein mu 2, was uniquely associated with the difference in temperature optimum of transcription (P = 0.0003). The L1 gene, which encodes minor core protein lambda 3 (previously implicated as the RNA polymerase), and the M1 gene were associated with the difference in absolute amounts of transcript produced (P = 0.01 and P = 0.0002, respectively). These data suggest that minor core protein mu 2 also plays a role in reovirus transcription.

Translation of the reovirus M1 gene initiates from the first AUG codon in both infected and transfected cells

Reovirus mu 2 protein can be expressed via the mouse phosphoglycerate kinase promoter to low levels in stably transfected L cells. To increase mu 2 expression, the terminal regions of the M1 gene cDNA constructs were modified and the effect on mu 2 expression was analyzed. The M1 gene has a single large open reading frame beginning at nucleotide 14 with another, in frame, AUG codon at nucleotide 161 reported to be used for translation initiation. Unexpectedly, deletions of the M1 5' terminal sequence upstream of the reported translation initiation codon, AUG161, resulted in loss of detection of mu 2 expression. When expression was driven by the stronger T7 promoter in the presence of recombinant vaccinia virus expressing the T7 RNA polymerase, constructs with the M1 5'-terminal deletion produced a smaller protein product of approximately 68 kDa, compared to approximately 73 kDa for the protein produced from the full-length M1-containing constructs consistent with the loss of 49 amino acids. The amount of shorter mu 2 product was increased by producing an improved 'Kozak' consensus sequence around the AUG codon at nucleotide 161 or by introducing an internal ribosome entry site at this location. Full-length M1 gene constructs produced a protein of the same size as the authentic mu 2 protein from virus-infected cells. It was further shown that the approximately 73 kDa product was expressed when the M1 gene was in different plasmid backgrounds and even when the M1 gene transcript was preceded by a 1 kb gene. This study demonstrated that translation of the reovirus M1 gene initiates from the first AUG codon in both infected and transfected cells.