Adenylic acid - rich sequences in influenza virus RNA.

Some influenza virus complementary RNA (cRNA) from infected chick cells is polyadenylated as judged by oligo(dT)-cellulose chromatography. However, none of the virion RNA or the vRNA synthesised in infected cells contain poly(A) sequences. cRNA containing poly(A) sequences was further characterised by polyacrylamide gel electrophoresis and under the conditions used only some size classes of cRNA were polyadenylated.     

Use of specific single stranded DNA probes cloned in M13 to study the RNA synthesis of four temperature-sensitive mutants of HK/68 influenza virus.

Specific single stranded DNA probes have been obtained for both influenza virion RNA (vRNA) and complementary RNA (cRNA) by cloning a hemagglutinin gene fragment in the single stranded DNA phase M13. These probes were used for hybridization with the total labeled RNA from cytoplasmic extracts of infected cells. MDCK cells were infected with temperature-sensitive mutants of influenza HK/68 and the production of the virus specific RNA species was analysed at both permissive and restrictive temperatures. Results show that two NP mutants which undergo intracistronic complementation exhibit two different phenotypes at the non permissive temperature: ts2C is poly A cRNA and vRNA negative whereas ts463 is RNA positive. Two mutants of P genes were also analysed and we discuss the relationship existing between the synthesis of the three RNA species especially between poly A and non poly A cRNA.     

cis-Acting signals in encapsidation of Hantaan virus S-segment viral genomic RNA by its N protein

The nucleocapsid (N) protein encapsidates both viral genomic RNA (vRNA) and the antigenomic RNA (cRNA), but not viral mRNA. Previous work has shown that the N protein has preference for vRNA, and this suggested the possibility of a cis-acting signal that could be used to initiate encapsidation for the S segment. To map the cis-acting determinants, several deletion RNA derivatives and synthetic oligoribonucleotides were constructed from the S segment of the Hantaan virus (HTNV) vRNA. N protein-RNA interactions were examined by UV cross-linking studies, filter-binding assays, and gel electrophoresis mobility shift assays to define the ability of each to bind HTNV N protein. The 5' end of the S-segment vRNA was observed to be necessary and sufficient for the binding reaction. Modeling of the 5' end of the vRNA revealed a possible stem-loop structure (SL) with a large single-stranded loop. We suggest that a specific interaction occurs between the N protein and sequences within this region to initiate encapsidation of the vRNAs.     

Coding assignments of double-stranded RNA segments of SA 11 rotavirus established by in vitro translation

The segmented double-stranded (ds) RNA genome of the simian rotavirus SA 11, after denaturation, can be translated in a cell-free protein synthesizing system. Of the 11 genome segments, 9 can be resolved on polyacrylamide gels and thus could be individually isolated and translated, providing a means of identifying the polypeptide encoded by each segment. On the basis of electrophoretic mobility of products in sodium dodecyl sulfate-polyacrylamide gels, the probable gene-coding assignments of dsRNA segments 1 to 6 were determined. RNA segments 1 to 4 code for polypeptides I1, I2, I3, and I4, respectively; segment 5 codes for a polypeptide very similar in mobility to a minor polypeptide present in SA 11-infected cells, O1A; and segment 6 codes for the major inner-capsid polypeptide I5.     

Characterization of polysome-associated RNA from influenza virus-infected cells.

Virus-specific polysome-associated RNA (psRNA) and RNA after dissociation of polysomes were analyzed by direct hybridization with unlabeled viral RNA (vRNA) and complementary RNA (cRNA). psRNA after a 30-min pulse with [3H]uridine contained 28% labeled cRNA, 70% host RNA, and no vRNA. After dissociation, psRNA sedimented heterogeneously. Heavy RNA (greater than 60S), ribosomal subunit RNA (rsuRNA, 30-60S), free mRNA (fmRNA, 10-30S), and light RNA (less than 10S) contained 16%, 54%, 70% and 28% cRNA, respectively, but no vRNA. When actinomycin D (AcD) was added at 2 h postinfection, the nature of the psRNA depended on the concentration of AcD and the condition of the labeling. At AcD concentrations of 1 mug or more per ml, no detectable vRNA or cRNA was associated with polysomes. At 0.2 mug of AcD per ml (a concentration that partially inhibited cRNA synthesis) and 2 h of labeling at 2.5 h postinfection, psRNA contained 40% viral-specific RNA, which included both vRNA and cRNA in almost equal amounts. When polysomes were dissociated, however, viral-specific fm RNA from AcD-treated cells contained exclusively cRNA and no detectable vRNA. Increasing amounts of labeled vRNA were present in the heavy region of the gradient (and in the pellet), which also contained varying amounts of cRNA. The labeled vRNA appears to be associated with polysomes in a cesium chloride density gradient (rho = 1.525 g/ml). Although we have ruled out the trivial explanation of viral ribonucleoprotein contamination,the nature of the complex containing both polysomes and vRNA is unknown.     

Purification of influenza viral complementary RNA: its genetic content and activity in wheat germ cell-free extracts.

Influenza viral complementary RNA (cRNA) was purified free from any detectable virion-type RNA (vRNA), and its genetic content and activity in wheat germ cell-free extracts were examined. After phenol-chloroform extraction of cytoplasmic fractions from infected cells, poly(A)-containing viral cRNA is found in two forms: in single-stranded RNA and associated with vRNA in partially and fully double-stranded RNA. To purify single-stranded cRNA free of these double-stranded forms, it was necessary to employ, as starting material, RNA fractions in which cRNA was predominantly single stranded. Two RNA fractions were successfully employed as starting material: polyribosomal RNA and the total cytoplasmic RNA from infected cells treated with 100 mug of cycloheximide (CM) per ml at 3 h after infection. In WSN virus-infected canine kidney (MDCK) cells, the addition of CM at 3 h after infection stimulates the production of cRNA threefold and causes a very large increase in the proportion of the cytoplasmic cRNA which is single stranded; double-stranded RNA forms are greatly reduced in amount. Total cRNA was obtained by oligo(dT)-cellulose chromatography, and single-stranded cRNA was separated from double-stranded forms by Sepharose 4B chromatography. The cRNA preparation purified from polyribosomes consists of 95% single-stranded cRNA, with the remaining 5% apparently being double-stranded RNA forms. The cRNA preparation purified from CM-treated cells (CM cRNA) is even more pure: 100% of the radiolabeled RNA is single-stranded cRNA. Annealing experiments, in which a limited amount of 32P-labeled genome RNA was annealed to the cRNA, indicate that the purified cRNA contains at least 84 to 90% of the genetic information in the vRNA genome. Purified viral cRNA (CM cRNA) is very active in directing the synthesis of virus-specific proteins in wheat germ cell-free extracts.     

A mutation on influenza C virus M1 protein affects virion morphology by altering the membrane affinity of the protein

Reverse genetics has been documented for influenza A, B, and Thogoto viruses belonging to the family Orthomyxoviridae. We report here the reverse genetics of influenza C virus, another member of this family. The seven viral RNA (vRNA) segments of C/Ann Arbor/1/50 were expressed in 293T cells from cloned cDNAs, together with nine influenza C virus proteins. At 48 h posttransfection, the infectious titer of the culture supernatant was determined to be 2.51 x 10(3) 50% egg infectious doses/ml, which is lower than the number of influenza C virus-like particles (VLPs) (10(6)/ml) generated using the same system. By generating influenza C VLPs containing a given vRNA segment, we showed that each of the vRNA segments was similarly synthesized in the plasmid-transfected cells but that some segments were less efficiently incorporated into the VLPs. This finding leads us to speculate that the differences in incorporation efficiency into VLPs between segments might be a reason for the inefficient production of infectious viruses. Second, we generated a mutant recombinant virus, rMG96A, which possesses an Ala-->Thr mutation at residue 24 of the M1 protein, a substitution demonstrated to be involved in the morphology (filamentous or spherical) of the influenza C VLPs. As expected, rMG96A exhibited a spherical morphology, whereas recombinant wild-type of C/Ann Arbor/1/50, rWT, exhibited a mainly filamentous morphology. Membrane flotation analysis of the cells infected with rWT or rMG96A revealed a difference in the ratio of membrane-associated M1 proteins, suggesting that the affinity of M1 protein to the cell membrane is a determinant for virion morphology.     

Distinct regions of influenza virus PB1 polymerase subunit recognize vRNA and cRNA templates.

The influenza virus RNA polymerase is a heterotrimer comprising the PB1, PB2 and PA subunits. PB1 is the core of the complex and accounts for the polymerase activity. We have studied the interaction of PB1 with model cRNA template by in vitro binding and Northwestern analyses. The binding to model cRNA was specific and showed an apparent Kd of approximately 7x10(-8) M. In contrast to the interaction with vRNA, PB1 was able to bind equally the 5' and 3' arm of the cRNA panhandle. The N-terminal 139 amino acids of PB1 and sequences between positions 267 and 493 proved positive for binding to cRNA, whereas the interaction with vRNA template previously was mapped to the N- and C-terminal regions. Competition experiments using the 5' and 3' arms of either the vRNA or cRNA panhandle indicated that the N-terminal binding site is shared by both templates. The data indicate that the PB1 RNA-binding sites are constituted by: (i) residues located at the N-terminus (probably common for vRNA and cRNA binding) and, either (ii) residues from the central part of PB1 (for cRNA) or (iii) residues from the C-terminal region of PB1 (for vRNA), and suggest that PB1 undergoes a conformational change upon binding to cRNA versus vRNA templates.     

The packaging signal of influenza viral RNA molecules.

The packaging signal present in influenza viral RNA molecules is shown not to constitute a separate structural element, but to reside within the 5'-bulged promoter structure, as caused by the central unpaired residue A10 in its 5' branch. Upon insertion of two uridine residues in the 3' branch opposite A10, the minus-strand viral RNA (vRNA) promoter is converted into a 3'-bulged structure, whereas the plus-strand cRNA promoter instead adopts the 5'-bulged conformation. In this promoter variant it is exclusively the cRNA that is found packaged in the progeny virions. Upon insertion of only a single uridine nucleotide opposite 5'A10, the two debulged structures of the vRNA and cRNA promoters are rendered identical, and both vRNA and cRNA molecules are packaged indiscriminately, in a 1:1 ratio, but at lower rates. We propose that the binding interactions of viral polymerase with either of the two differently bulged vRNA and cRNA promoter structures result in two different conformations of the enzyme protein. Only the 5' bulged RNA-associated polymerase conformation appears to be recognized for nuclear export, which depends on nuclear matrix protein M1 and nonstructural protein NS2. And the respective wild-type vRNP- or insertion mutant cRNP complex is observed to enter the cytoplasm and hence is included in the viral encapsidation process, which takes place at the plasma membrane.     

Homologous terminal sequences of the genome double-stranded RNAs of bluetongue virus.

The 3'-terminal sequences of the 10 double-stranded RNA genome segments of bluetongue virus (serotypes 10 and 11) were determined. The double-stranded RNAs were 3' labeled with [5'-32P]pCp and resolved into 10 segments by electrophoresis. After denaturation, the two complementary strands of segments 4 through 10 were resolved into fast- and slow-migrating species by polyacrylamide gel electrophoresis, and their 3' end sequences were determined. Complete RNase T1 digestion of the individual 3'-labeled double-stranded RNA segments yielded two labeled oligonucleotides, one of which migrated faster than the other on 20% polyacrylamide-7 M urea gels. Sequence analyses of the two oligonucleotides of segments 4 through 10 confirmed the corresponding RNA sequence data. For RNA segments 1 through 3 the oligonucleotide analyses gave comparable results. The 3'-terminal sequences of the fast-migrating RNA species were HOCAAUUU. . . ; those of the slow-migrating RNA species were HOCAUUCACA. . . . Similar results were obtained for double-stranded RNA from bluetongue virus serotypes 10 and 11. Beyond the common termini, the sequences for each segment varied considerably.     

The genome of Uukuniemi virus consists of three unique RNA segments

The three RNA species isolated from virions of Uukuniemi virus, a proposed member of the newly defined Bunyaviridae family, have been characterized by analysis of ³²P-labeled ribonuclease T1 oligonucleotides separated on two-dimensional polyacrylamide gels. Each RNA species contains unique oligonucleotides not present in the two others, indicating that the genome of this virus is segmented. Each segment appears to contain a unique primary sequence with little or no overlapping among the segments. The complexities of the RNA segments as calculated from the radioactivity in unique oligonucleotides of defined lengths are about 8000 (L RNA), 3500 (M) and 1900 (S) nucleotides. Since these values are similar to the molecular weights determined by other methods, each size class of RNA corresponds to a single molecular species. The presence of a 5′ terminal pppAp … structure in each RNA segment confirms indications from electron microscopy that the apparently circular RNA segments are not covalently closed. The absence of either a 5′ terminal “cap” or 3′ terminal poly(A) supports the concept that Uukuniemi virus is a negative strand virus.     

Influenza A Virus Assembly Intermediates Fuse in the Cytoplasm

Reassortment of influenza viral RNA (vRNA) segments in co-infected cells can lead to the emergence of viruses with pandemic potential. Replication of influenza vRNA occurs in the nucleus of infected cells, while progeny virions bud from the plasma membrane. However, the intracellular mechanics of vRNA assembly into progeny virions is not well understood. Here we used recent advances in microscopy to explore vRNA assembly and transport during a productive infection. We visualized four distinct vRNA segments within a single cell using fluorescent in situ hybridization (FISH) and observed that foci containing more than one vRNA segment were found at the external nuclear periphery, suggesting that vRNA segments are not exported to the cytoplasm individually. Although many cytoplasmic foci contain multiple vRNA segments, not all vRNA species are present in every focus, indicating that assembly of all eight vRNA segments does not occur prior to export from the nucleus. To extend the observations made in fixed cells, we used a virus that encodes GFP fused to the viral polymerase acidic (PA) protein (WSN PA-GFP) to explore the dynamics of vRNA assembly in live cells during a productive infection. Since WSN PA-GFP colocalizes with viral nucleoprotein and influenza vRNA segments, we used it as a surrogate for visualizing vRNA transport in 3D and at high speed by inverted selective-plane illumination microscopy. We observed cytoplasmic PA-GFP foci colocalizing and traveling together en route to the plasma membrane. Our data strongly support a model in which vRNA segments are exported from the nucleus as complexes that assemble en route to the plasma membrane through dynamic colocalization events in the cytoplasm.     

RNA associated with murine intracisternal type A particles codes for the main particle protein.

Intracisternal type A particles were isolated from MOPC-104E myeloma grown subcutaneously and from N 4 neuroblastoma cells in culture. Polyadenylated RNA was prepared from the particles and tested in a cell-free translation system derived from rabbit reticulocytes. RNA from the two sources directed the synthesis of multiple polypeptides with similar distributions of electrophoretic mobilities in sodium dodecyl sulfate-containing polyacrylamide gels, including one conponent of the same size as the major A-particle structural protein (73,000 daltons). Analysis of the RNAs by electrophoresis in methyl mercury-containing agarose gels revealed a 35S component common to A-particles from both cell types. This was a major component of the N4 preparations, whereas a 28S species predominated in the case of MOPC-104E. These two RNAs (35S from N4 cells and 28S from MOPC-104E), when isolated on isokinetic sucrose gradients, each directed the synthesis of a 73,000-molecular-weight polypeptide that comigrated on gels with authentic A-particle structural protein. Idnetity of the cell-free product was confirmed by two-dimensional analysis of the [35S]methionine-labeled tryptic peptides. The N4 RNA preparations also contained a major32S component which did not code effectively for the A-particle structural protein.     

Differences in the poly(ADP-ribosyl)ation patterns of ICP4, the herpes simplex virus major regulatory protein, in infected cells and in isolated nuclei.

Infected-cell protein 4 (ICP4), the major regulatory protein in herpes simplex viruses 1 and 2, was previously reported to accept 32P from [32P]NAD in isolated nuclei. This modification was attributed to poly(ADP-ribosyl)ation (C. M. Preston and E. L. Notarianni, Virology 131:492-501, 1983). We determined that an antibody specific for poly(ADP-ribose) reacts with ICP4 extracted from infected cells, electrophoretically separated in denaturing gels, and electrically transferred to nitrocellulose. Our results indicate that all forms of ICP4 observed in one-dimensional gel electrophoresis are poly(ADP-ribosyl)ated. Poly(ADP-ribose) on ICP4 extracted from infected cells was resistant to cleavage by purified poly(ADP-ribose) glycohydrolase unless ICP4 was in a denatured state. Poly(ADP-ribose) added to ICP4 in isolated nuclei was sensitive to this enzyme. This result indicates that the two processes are distinct and may involve different sites on the ICP4 molecule.     

Genetic mapping of reovirus virulence and organ tropism in severe combined immunodeficient mice: organ-specific virulence genes.

We used reovirus reassortant genetics and severe combined immunodeficient (SCID) mice to define viral genes important for organ tropism and virulence in the absence of antigen-specific immunity. Adult SCID mice infected with reovirus serotype 1 strain Lang (T1L) died after 20 +/- 6 days, while infection with serotype 3 strain Dearing (T3D) was lethal after 77 +/- 22 days. One hundred forty-five adult SCID mice were infected with T1L, T3D, and 25 different T1L x T3D reassortant reoviruses, and gene segments associated with the increased virulence of T1L were identified. Gene segments S1, L2, M1, and L1 accounted for > 90% of the genetically determined increase in T1L virulence. Gene segment M1 was independently important for virulence, with S1, L2, and L1 alone or in combination also playing a role. T1L grew to higher titers in multiple organs and caused more severe hepatitis than T3D. Seventy adult SCID mice, T1L, T3D, and 15 T1L x T3D reassortant viruses were used to map genetic determinants of viral titers in the brain, intestines, and liver, as well as the severity of hepatitis. Different sets of gene segments were important for determining viral titers in different organs. Gene segments L1 (encoding a core protein) and L2 (encoding the core spike of the virion) were important in all of the organs analyzed. The M1 gene segment (encoding a core protein), but not the S1 gene segment, was a critical determinant of reovirus titer in the liver and severity of hepatitis. The S1 gene segment (encoding the viral cell attachment protein and a nonstructural protein), but not the M1 gene segment, was a critical determinant of titers in intestines and brains. These studies demonstrate that viral growth in different organs is dependent on different subsets of the genes important for virulence. The virion-associated protein products of the four gene segments (L1, L2, M1, and S1) important for virulence and organ tropism in SCID mice likely form a structural unit, the reovirus vertex. Organs (the brain and intestines versus the liver) differ in properties that determine which virulence genes, and thus which parts of this structural unit, are important.