Analysis of Nuclear Accumulation of Influenza NP Antigen in von Magnus Virus-Infected Cells

When 1–5C-4 cells were infected with von Magnus virus derived from influenza A/RI/5⁺ virus by four successive undiluted passages in chick embryos, virus-specific proteins were synthesized but production of infectious virus was inhibited. In these cells the synthesis of viral RNA was suppressed and the nucleoprotein (NP) antigen was found predominantly in the nucleus in contrast to standard virus-infected cells in which the antigen was distributed throughout the whole cell. The intracellular location and migration of NP were determined by isotope labeling and sucrose gradient centrifugation of subcellular fractions. In standard virus-infected cells NP polypeptide was present predominantly in the cytoplasm in the form of viral ribonucleoprotein (RNP) and intranuclear RNP was detected in reduced amounts. In contrast, in von Magnus virus-infected cells NP polypeptide was present predominantly in the nucleus in a nonassembled, soluble form and the amount of cytoplasmic RNP was considerably reduced. After short-pulse labeling NP was detected exclusively in the cytoplasm in a soluble form and after a chase a large proportion of such soluble NP was seen in the nucleus. It is suggested that a large proportion of the NP synthesized in von Magnus virus-infected cells is not assembled into cytoplasmic RNP because of the lack of available RNA and the NP migrated into the nucleus and remained there.     

Virological, Immunochemical, and Cytochemical Studies of Four HeLa Cell Lines Infected with Two Strains of Influenza Virus

The production of infectious virus, hemagglutinin, and viral (V) antigens and the changes in ribonucleoprotein (RNP) and lipoprotein metabolism have been studied in four sublines of HeLa cells infected with the PR8 and a PR8 recombinant strain of influenza virus. Much greater amounts of infectious virus and much less hemagglutinin were produced by the PR8 recombinant than by PR8 virus in all four cell lines. Different amounts of infectious virus per infected cell were produced by the recombinant in the four cell lines, whereas very little infectious virus was produced by the PR8 strain in any of the HeLa cells. In all cell lines infected with both strains of virus, "soluble" (S) antigen appeared early in the nucleolus. In cells infected with PR8 recombinant, S antigen subsequently filled the nucleus and later appeared in the cytoplasm. In most cells infected with PR8 virus, nuclear S antigen did not fuse to fill the nucleus, and S antigen was not detected in the cytoplasm. V antigen was observed in the cytoplasm of cells when diffuse nuclear S antigen had formed. The earliest and most frequent change in the RNP of the infected cells was a decrease in stainable RNP spherules (nucleolini) in the nucleolus. This was followed, in a smaller proportion of cells, by the appearance of nuclear and cytoplasmic inclusions containing RNP. There was a characteristic difference in the morphology of the cytoplasmic inclusions produced by the two strains of virus, but the same types of inclusions were observed in all four HeLa lines. A significant increase in lipoprotein was observed only in association with the cytoplasmic inclusions produced by PR8 recombinant virus. There was a striking difference in the proportion of cells with cytochemical changes in RNP in the four cell lines. A significant cytopathic effect (CPE) was observed only in three virus-cell systems in which a high proportion of cells exhibited changes in nucleolinar RNP. It is suggested that disappearance of RNP in the nucleolini may be an indication of shutdown of host ribonucleic acid synthesis and that this in turn results in a CPE. Virus infection resulted in a C-mitotic block that was followed by karyorrhexis. Infection of the cell did not always result in the production of infectious virus, in changes in the RNP of the nucleolini, in the development of nuclear or cytoplasmic RNP inclusions, or in CPE. The results suggest that production of infectious virus, shutdown of cellular RNP synthesis with accompanying CPE, and the formation of inclusions appear to be independent events.     

Modulation of Nuclear Localization of the Influenza Virus Nucleoprotein through Interaction with Actin Filaments

The influenza virus genome is transcribed in the nuclei of infected cells but assembled into progeny virions in the cytoplasm. This is reflected in the cellular distribution of the virus nucleoprotein (NP), a protein which encapsidates genomic RNA to form ribonucleoprotein structures. At early times postinfection NP is found in the nucleus, but at later times it is found predominantly in the cytoplasm. NP contains several sequences proposed to act as nuclear localization signals (NLSs), and it is not clear how these are overridden to allow cytoplasmic accumulation of the protein. We find that NP binds tightly to filamentous actin in vitro and have identified a cluster of residues in NP essential for the interaction. Complexes containing RNA, NP, and actin could be formed, suggesting that viral ribonucleoproteins also bind actin. In cells, exogenously expressed NP when expressed at a high level partitioned to the cytoplasm, where it associated with F-actin stress fibers. In contrast, mutants unable to bind F-actin efficiently were imported into the nucleus even under conditions of high-level expression. Similarly, nuclear import of NLS-deficient NP molecules was restored by concomitant disruption of F-actin binding. We propose that the interaction of NP with F-actin causes the cytoplasmic retention of influenza virus ribonucleoproteins.     

Hepatitis delta virus ribonucleoproteins shuttle between the nucleus and the cytoplasm

Hepatitis delta virus (HDV) infection of individuals infected with hepatitis B virus (HBV) is associated with more severe liver damage and an increased risk of fulminant disease. HDV is a single-stranded RNA virus that encodes a single protein, the delta antigen, which is expressed in two forms, small (S-HDAg) and large (L-HDAg). Here we show that although HDV ribonucleoproteins are mainly detected in the nucleus, they are also present in the cytoplasm of cells infected with HDV or transfected with HDV cDNA. Making use of an heterokaryon assay, we demonstrate that HDV ribonucleoproteins shuttle continuously between the nucleus and the cytoplasm. In the absence of HDV RNA, both forms of the delta antigen are retained in the nucleus, whereas in the absence of the delta antigen, HDV RNA is predominantly detected in the cytoplasm. Coexpression of HDV RNA and S-HDAg (which binds to the viral RNA and contains a nuclear localization signal) results in nuclear accumulation of the viral RNA. This suggests that HDV RNA mediates export of viral particles to the cytoplasm whereas the delta antigen triggers their reimport into the nucleus.     

Regulation of simian virus 40 gene expression in Xenopus laevis oocytes.

Expression of the simian virus 40 (SV40) early and late regions was examined in Xenopus laevis oocytes microinjected with viral DNA. In contrast to the situation in monkey cells, both late-strand-specific (L-strand) RNA and early-strand-specific (E-strand) RNA could be detected as early as 2 h after injection. At all time points tested thereafter, L-strand RNA was synthesized in excess over E-strand RNA. Significantly greater quantities of L-strand, relative to E-strand, RNA were detected over a 100-fold range of DNA concentrations injected. Analysis of the subcellular distribution of [35S]methionine-labeled viral proteins revealed that while the majority of the VP-1 and all detectable small t antigen were found in the oocyte cytoplasm, most of the large T antigen was located in the oocyte nucleus. The presence of the large T antigen in the nucleus led us to investigate whether this viral product influences the relative synthesis of late or early RNA in the oocyte as it does in infected monkey cells. Microinjection of either mutant C6 SV40 DNA, which encodes a large T antigen unable to bind specifically to viral regulatory sequences, or deleted viral DNA lacking part of the large T antigen coding sequences yielded ratios of L-strand to E-strand RNA that were similar to those observed with wild-type SV40 DNA. Taken together, these observations suggest that the regulation of SV40 RNA synthesis in X. laevis oocytes occurs by a fundamentally different mechanism than that observed in infected monkey cells. This notion was further supported by the observation that the major 5' ends of L-strand RNA synthesized in oocytes were different from those detected in infected cells. Furthermore, only a subset of those L-strand RNAs were polyadenylated.     

Defective Influenza Viral Ribonucleoproteins Cause Interference

Ribonucleoproteins (RNPs) isolated from infectious and defective interfering (DI) influenza virus (WSN) contained three major RNP peaks when analyzed in a glycerol gradient. Peak I RNP was predominant in infectious virus but was greatly reduced in DI virus preparations. Conversely, peak III RNP was elevated in DI virus, suggesting a large increase in DI RNA in this fraction. Labeled [(32)P]RNA was isolated from each RNP region and analyzed by electrophoresis on polyacrylamide gels. Peak I RNP contained primarily the polymerase and some HA genes, peak II contained some HA gene but mostly the NP and NA genes, and peak III contained the M and NS genes. In addition, peak III RNP from DI virus also contained the characteristic DI RNA segments. Interference activity of RNP fractions isolated from infectious and DI virus was tested using infectious center reduction assay. RNP peaks (I, II, and III) from infectious virus did not show any interference activity, whereas the peak III DI RNP caused a reduction in the number of infectious centers as compared to controls. Similar interference was not demonstrable with peak I RNP of DI virus nor with any RNP fractions from infectious virus alone. The interference activity of RNP fractions was RNase sensitive, suggesting that the DI RNA contained in DI RNPs was the interfering agent, and dilution experiments supported the conclusion that a single DI RNP could cause interference. The interfering RNPs were heterogeneous, and the majority migrated slower than viral RNPs containing M and NS genes. These results suggest that DI RNP (or DI RNA) is also responsible for interference in segmented, negative-stranded viruses.     

反义寡核苷酸prop5在A549细胞内具有抗流感病毒活性

目的：研究硫代反义寡核苷酸prop5在细胞水平的抗流感活性及其作用机制。方法：cy3标记prop5用于考查人肺腺癌细胞A549对硫代反义寡核酸的摄取;利用实时荧光定量PCR检测流感病毒RNA拷贝数,Western印迹检测prop5对PDCD5蛋白表达和caspase-3蛋白剪切的抑制;利用间接免疫荧光和Western印迹检测prop5对病毒核糖核蛋白复合体（RNP）出核的影响;利用TUNEL检测prop5对流感病毒引起细胞凋亡的抑制作用。结果：流感病毒感染促进A549细胞摄取prop5;prop5下调感染病毒的A549细胞中PDCD5蛋白的表达,并能抑制流感病毒的复制;prop5抑制流感病毒引起的A549细胞的凋亡;prop5抑制病毒RNP出核。结论：prop5在细胞水平具有抗流感病毒活性,其作用机制可能同抑制RNP出核有关;本研究为进一步探讨宿主-病毒相互作用和抗流感药物开发奠定了基础。     

The use of a complementary DNA probe to detect accumulation of mengo RNA in infected cells pretreated with interferon.

Complementary DNA (cDNA) from Mengo virus RNA has been synthesized and used as a probe to measure the synthesis and accumulation of viral RNA in Mengo infected L cell cultures, treated or untreated with interferon. Under experimental conditions used (200 units interferon/ml and 50 virus plaque-forming units/cell) results show that there is some synthesis of Mengo virus RNA in cells treated with interferon. One hour after infection, treated cells contain three times less viral RNA than untreated cells; five hours after infection, this difference has increased to ten fold. As in the control, no fragmented Mengo virus RNA molecules were found in interferon treated cells. The smaller recovery of infectious particles from interferon treated cells as compared to RNA accumulation suggests that not only RNA accumulation is inhibited but also a step posterior in viral maturation.     

Characterization of intracellular viral RNA in interferon-treated cells chronically infected with murine leukemia virus.

We have recently found that Moloney murine leukemia virus assembles within cytoplasmic vacuoles of chronically infected NIH/3T3 cells rather than at their surface (submitted for publication). In the present study we found that if these cells were treated with interferon (IF) for 24 to 48 h the intracellular virus particles accumulated at a two- to threefold-higher level than that observed in untreated cells. Nevertheless, despite this accumulation, no difference between IF-treated and untreated cells was observed in the amount of the total cytoplasmic viral RNA or in its 35S or 21S species. When cellular virions were sedimented from the cytoplasmic fraction, a markedly higher amount of viral RNA was detected in the viral pellet of IF-treated cells than was detected in untreated cells, whereas the amount of viral RNA left in the virus-free cytoplasm of IF-treated cells was much lower than that in the untreated cells. Furthermore, the amount of the cytoplasmic polyriboadenylic acid-containing viral RNA was also remarkably higher in the IF-treated cells. Viral polyribosomes appeared to be fully functional in IF-treated cells, since no effect of IF on viral protein synthesis could be detected. Analysis of the nuclear viral RNA showed no difference between IF-treated and untreated cells after 24 h of IF treatment. Both contained a comparable amount of 35S viral RNA. However, at 48 h a significant accumulation of viral RNA was observed in the nucleus of the IF-treated cells as compared with the untreated cells, although in both cases only 35S species were evident. This accumulation appeared to activate a degradation process which destroyed nuclear viral RNA, since a dramatic shift toward smaller-sized molecules of viral RNA and a remarkable reduction in its amount were observed after 72 h of IF treatment.     

Regulation of influenza virus RNA polymerase activity by cellular and viral factors.

An in vitro RNA synthesis system mimicking replication of genomic influenza virus RNA was developed with nuclear extracts prepared from influenza virus-infected HeLa cells using exogenously added RNA templates. The RNA synthesizing activity was divided into two complementing fractions, i.e. the ribonucleoprotein (RNP) complexes and the fraction free of RNP, which could be replaced with RNP cores isolated from virions and nuclear extracts from uninfected cells, respectively. When nuclear extracts from uninfected cells were fractionated by phosphocellulose column chromatography, the stimulatory activity for RNA synthesis was further separated into two distinct fractions. One of them, tentatively designated RAF (RNA polymerase activating factor), stimulated RNA synthesis with either RNP cores or RNA polymerase and nucleocapsid protein purified from RNP cores as the enzyme source. In contrast, the other, designated PRF (polymerase regulating factor), functioned as an activator only when RNP cores were used as the enzyme source. Biochemical analyses revealed that PRF facilitates dissociation of RNA polymerase from RNP cores. Of interest is that virus-coded non-structural protein 1 (NS1), which has been thought to be involved in regulation of replication, counteracted PRF function. Roles of cellular factors and viral proteins, NS1 in particular, are discussed in terms of regulation of influenza virus RNA genome replication.     

Vaccinia virus RNA polymerase associated with nuclei of infected HeLa cells.

Though vaccinia virus DNA and RNA replication take place predominantly in the cytoplasm of an infected cell, virus formation requires the presence of a functional nucleus in a yet undefined manner. When the nuclei from cells infected for 3 h are isolated and purified, they are found to synthesize five times more RNA in vitro than do corresponding nuclei from noninfected cells. Fifty percent of the RNA synthesized in vitro by nuclei from infected cells is vaccinia specific, and this vaccinia RNA synthesis is resistant to alpha-amanitin concentrations up to 100 micrograms/ml. Furthermore, when the RNA polymerase activities of these nuclei are separated on DEAE-Sephadex columns, 56% of the total nuclear enzyme activity is found to be the vaccinia-specific RNA polymerase known to be alpha-amanitin resistant. The nucleus associated vaccinia RNA polymerase represents 18% of the total cellular vaccinia RNA polymerase. This synthesis of vaccinia RNA in the nucleus may explain the nuclear requirement for vaccinia virus maturation.     

Hyperphosphorylation of mutant influenza virus matrix protein, M1, causes its retention in the nucleus.

The matrix (M1) protein of influenza virus is a major structural component, involved in regulation of viral ribonucleoprotein transport into and out of the nucleus. Early in infection, M1 is distributed in the nucleus, whereas later, it is localized predominantly in the cytoplasm. Using immunofluorescence microscopy and the influenza virus mutant ts51, we found that at the nonpermissive temperature M1 was retained in the nucleus, even at late times after infection. In contrast, the viral nucleoprotein (NP), after a temporary retention in the nucleus, was distributed in the cytoplasm. Therefore, mutant M1 supported the release of the viral ribonucleoproteins from the nucleus, but not the formation of infectious virions. The point mutation in the ts51 M1 gene was predicted to encode an additional phosphorylation site. We observed a substantial increase in the incorporation of 32Pi into M1 at the nonpermissive temperature. The critical role of this phosphorylation site was demonstrated by using H89, a protein kinase inhibitor; it inhibited the expression of the mutant phenotype, as judged by M1 distribution in the cell. Immunofluorescence analysis of ts51-infected cells after treatment with H89 showed a wild-type phenotype. In summary, the data indicated that the ts51 M1 protein was hyperphosphorylated at the nonpermissive temperature and that this phosphorylation was responsible for its aberrant nuclear retention.