Analysis of a Viral Agent Isolated from Multiple Sclerosis Brain Tissue: Characterization as a Parainfluenzavirus Type 1

A virus originally isolated from cell cultures obtained by lysolecithin-induced fusion of human multiple sclerosis brain cells with CV-1 cells has been analyzed for its antigenic, RNA, and polypeptide compositions, and for selective biological properties. Our findings establish that this isolate, designated 6/94 virus, contains a 50S RNA genome and is, as yet, indistinguishable from Sendai virus in its antigenic and total polypeptide compositions. Despite these similarities, the 6/94 and Sendai viruses differ in certain phenotypic properties. 6/94 virus is markedly less cytocidal for chick fibroblasts, especially at 37 C and, after beta-propiolactone inactivation, it possesses a greater capacity for cell fusion and a lower toxicity than does comparably treated Sendai virus. In addition, 6/94 virus shows greater hemolytic activity.     

Replication of Sendai Virus: II. Steps in Virus Assembly

Chick embryo fibroblast cultures infected with Sendai virus were incubated with (3)H-uridine in the presence of actinomycin D beginning at 18 hr after infection. The 35 and 18S virus-specific ribonucleic acid (RNA) components were found in a ribonuclease-sensitive form in the cell and appeared to be associated with polyribosomes. Newly synthesized 57S viral RNA was rapidly coated with protein to form intracellular viral nucleocapsid, and no 57S RNA was found "free" (ribonucleasesensitive) in the 2,000 x g supernatant fraction of disrupted cells. The nucleocapsid from detergent-disrupted Sendai virus and that from disrupted cells were indistinguishable in ultrastructure and buoyant density, and neither was found to be infectious or have hemagglutinating activity. Kinetic studies of nucleocapsid and virus formation indicated a relative block in conversion of viral nucleocapsid to complete enveloped virus in these cells, resulting in accumulation of large amounts of nucleocapsid in the cell cytoplasm.     

The rule of six, a basic feature for efficient replication of Sendai virus defective interfering RNA.

The addition of the hepatitis delta virus genomic ribozyme to the 3' end sequence of a Sendai virus defective interfering RNA (DI-H4) allowed the reproducible and efficient replication of this RNA by the viral functions expressed from cloned genes when the DI RNA was synthesized from plasmid. Limited nucleotide additions or deletions (+7 to -7 nucleotides) in the DI RNA sequence were then made at five different sites, and the different RNA derivatives were tested for their abilities to replicate. Efficient replication was observed only when the total nucleotide number was conserved, regardless of the modifications, or when the addition of a total of 6 nucleotides was made. The replicated RNAs were shown to be properly enveloped into virus particles. It is concluded that, to form a proper template for efficient replication, the Sendai virus RNA must contain a total number of nucleotides which is a multiple of 6. This was interpreted as the need for the nucleocapsid protein to contact exactly 6 nucleotides.     

Ribonucleic Acid Polymerase Induced in Cells Infected with Sendai Virus

A ribonucleic acid (RNA)-dependent RNA polymerase was induced in chick embryo fibroblast cells after infection with Sendai virus (parainfluenza 1 virus). The enzyme was associated with the microsomal fraction of infected cells and reached maximum detectable activity at 18 hr after virus infection. The activity of the enzyme in vitro was dependent on the presence of added magnesium ions and all four nucleoside triphosphates and was not inhibited by actinomycin D. The RNA synthesized by the enzyme in vitro was sensitive to ribonuclease and consisted of a complex mixture of RNA species including 34S, 24S, and 18S components. Similar RNA components were detected in the microsomal fraction of Sendai virus-infected cells by labeling with (3)H-uridine from 17 to 18 hr postinfection in the presence of actinomycin D. Of the RNA synthesized by Sendai virus-induced RNA polymerase in vitro, 98% became insensitive to ribonuclease after annealing with RNA extracted from purified Sendai virus particles.     

Fate of Sendai Virus Ribonucleoprotein in Virus-infected Cells

The cytoplasmic extracts of Ehrlich ascites tumor cells infected with (32)PO(4) and (3)H-leucine-labeled Sendai virus have been examined during the course of infection with respect to sedimentation behavior and buoyant densities of input virus radioactivity. It was found that (32)P and (3)H radioactivities were coincident, and, at 30 min after infection, the bulk of radioactivity was recovered in the polysome region of a sucrose gradient in the position of Sendai virus ribonucleoprotein (210S). The heterogeneity of radioactivity profiles appeared at 1 hr after infection and increased during 6 hr of incubation. The buoyant densities of input virus components were determined by banding in CsCl gradient. Here again the bulk of coincident (32)P and (3)H radioactivity at 30 min after infection banded at the same density as Sendai virus ribonucleoprotein (1.31 g/cm(3).) This component disappeared at 3 hr after infection, and (32)P and (3)H radioactivities were now found in components banded at densities 1.38, 1.41, 1.45, 1.49, and 1.55 g/cm(3). The results presented are consistent with the idea that virus ribonucleoprotein is retained in the cytoplasm of infected cells during at least 6 hr of incubation, being partly deproteinized in the course of infection. The nature of components which banded at rho = 1.41, 1.45, 1.49, and 1.55 as complexes of partly deproteinized ribonucleoprotein with ribosomes will be described in a separate paper.     

Molecular Weight Determination of Sendai and Newcastle Disease Virus RNA

The molecular weights of Sendai and Newcastle disease virus RNA were estimated by sedimentation in sucrose gradients and by length measurements in the electron microscope under both denaturing and nondenaturing conditions. Sedimentation analyses under denaturing conditions yielded molecular weight estimates of 2.3 x 10(6) to 2.6 x 10(6), whereas length measurements yielded estimates of 5.2 x 10(6) to 5.6 x 10(6) for both denatured and nondenatured viral RNA. It would appear that the conditions of denaturation used (99% dimethyl sulfoxide at 26 C, and reaction with 1.1 M formaldehyde for 10 min at 60 C) do not equally denature parainfluenza virus RNA and other RNAs, such as cellular rRNA, 45S rRNA precursor, and R17 RNA.     

Homologous Interference by Incomplete Sendai Virus Particles: Changes in Virus-Specific Ribonucleic Acid Synthesis

Incomplete Sendai virus particles (I particles) interfered with the replication of several strains of infectious Sendai virions (standard virus) but not with the replication of Newcastle disease virus, mumps virus, or Sindbis virus. I particles did not induce interferon, and ultraviolet irradiation of I particles abolished their ability to interfere. Protein synthesis was not necessary to establish interference. The degree of interference depended on the interval between exposure of cells to the I particles and challenge by standard virus, and this was reflected in the degree of inhibition of virus-specific ribonucleic acid (RNA) synthesis in infected cells. The most dramatic change was decreased accumulation of 50S virus-specific RNA in infected cells. RNA species sedimenting slower than 50S were not as markedly reduced in total amount, but hybridization experiments showed that a substantial portion of these slowly sedimenting RNA species were plus strands, presumably representing replicas of the RNA species in I particles. When I particles in insufficient numbers to interfere were added to cells as late as 8 hr after standard virus, there were no obvious changes in virus-specific RNA species in the cells; however, significant amounts of 19 and 25S RNA species, representing progeny of the I particles, appeared in the culture medium. It was concluded that interference was an intracellular event affecting an early step in virus replication. Competition by I particles for cell sites or substrates needed by standard virus seemed a less likely mechanism of interference than competition for enzymes specified by standard virus.     

活疫苗及其生产基质中Sendai病毒RT-PCR检测方法的研究

目的建立检测Sendai病毒的RT-PCR方法并应用于活疫苗及其生产基质中Sendai病毒的检测.方法将Sendai病毒E17株接种9日龄鸡胚尿囊腔,72h后收集尿囊液,用于提取病毒RNA,并逆转录成cDNA,用两对针对Sendai病毒NP基因设计的外引物和内引物分别进行扩增.扩增产物克隆于T-载体,并测序.尿囊液按10倍倍比稀释,进行敏感性实验.将该方法用于检测乙脑减毒活疫苗和用于生产疫苗用的普通级乳地鼠肾中的Sendai病毒.结果外引物和内引物的PCR分别扩增出684bp和248bp的片段,外引物PCR产物的测序结果与Genbank报告的序列完全一致.敏感性实验结果表明,第一次PCR可检测到10-4病毒滴度,巢式PCR可检测到10-7病毒滴度.乙脑减毒活疫苗和乳地鼠肾的检测结果为阴性.结论建立检测Sendai病毒的RT-PCR方法具有很高的特异性和敏感性.     

Sendai Virus Fusion Activity as Modulated by Target Membrane Components

We have studied the differences between erythrocytes and erythrocyte ghosts as target membranes for the study of Sendai virus fusion activity. Fusion was monitored continuously by fluorescence dequenching of R18-labeled virus. Experiments were carried out either with or without virus/target membrane prebinding. When Sendai virus was added directly to a erythrocyte/erythrocyte ghost suspension, fusion was always lower than that obtained when experiments were carried out with virus already bound to the erythrocyte/erythrocyte ghost in the cold, since with virus prebinding fusion can be triggered more rapidly. Although virus binding to both erythrocytes and erythrocyte ghosts was similar, fusion activity was much more pronounced when erythrocyte ghosts were used as target membranes. These observations indicate that intact erythrocytes and erythrocyte ghosts are not equivalent as target membranes for the study of Sendai virus fusion activity. Fusion of Sendai virus with both target membranes was inhibited when erythrocytes or erythrocyte ghosts were pretreated with proteinase K, suggesting a role of target membrane proteins in this process. Treatment of both target membranes with neuraminidase, which removes sialic acid residues (the biological receptors for Sendai virus) greatly reduced viral binding. Interestingly, this treatment had no significant effect on the fusion reaction itself.     

Adenylate-Rich Sequences in Sendai Virus Transcripts from Infected Cells

Virus-specific complementary ribonucleic acid (RNA) from cells infected with Sendai virus was isolated by a procedure involving hybridization with virion RNA and isopycnic centrifugation of the RNA hybrids. The complementary RNA contained adenylate-rich sequences which sedimented at about 4S.     

A Sendai Virus-Derived RNA Agonist of RIG-I as a Virus Vaccine Adjuvant

The innate immune system is responsible for recognizing invading pathogens and initiating a protective response. In particular, the retinoic acid-inducible gene 1 protein (RIG-I) participates in the recognition of single- and double-stranded RNA viruses. RIG-I activation leads to the production of an appropriate cytokine and chemokine cocktail that stimulates an antiviral state and drives the adaptive immune system toward an efficient and specific response against the ongoing infection. One of the best-characterized natural RIG-I agonists is the defective interfering (DI) RNA produced by Sendai virus strain Cantell. This 546-nucleotide RNA is a well-known activator of the innate immune system and an extremely potent inducer of type I interferon. We designed an in vitro-transcribed RNA that retains the type I interferon stimulatory properties, and the RIG-I affinity of the Sendai virus produced DI RNA both in vitro and in vivo. This in vitro-synthesized RNA is capable of enhancing the production of anti-influenza virus hemagglutinin (HA)-specific IgG after intramuscular or intranasal coadministration with inactivated H1N1 2009 pandemic vaccine. Furthermore, our adjuvant is equally effective at increasing the efficiency of an influenza A/Puerto Rico/8/34 virus inactivated vaccine as a poly(I·C)- or a squalene-based adjuvant. Our in vitro-transcribed DI RNA represents an excellent tool for the study of RIG-I agonists as vaccine adjuvants and a starting point in the development of such a vaccine.     

Genomic and copy-back 3'' termini in Sendai virus defective interfering RNA species

Direct sequencing of nine Sendai virus defective interfering RNA species revealed two kinds of 3'-terminal sequences. Six RNA species had 3' termini identical to the virus genome (negative strand), confirming that internal deletions are a frequent cause of Sendai virus defectiveness. The other three RNA species had 3'-terminal sequences identical to that described as the complement of the 5' terminus of the virus genome (R. A. Lazzarini, J. D. Keene, and M. Schubert, Cell 26:145-154, 1981), indicating that they are of the copy-back type. Extensive homology between these two types of 3' sequences evidently accounts for the ability of the copy-back sequence to function as an initiation signal for viral RNA replication. There may not be a selective advantage of one type of terminus over the other, since one defective interfering strain possessed two RNA species, one of which had the genomic 3' terminus and the other copy-back type.     

仙台病毒RT-PCR检测方法的建立及灰仓鼠中流行情况调查

目的建立仙台病毒（SV）RT-PCR检测方法,并对灰仓鼠仙台病毒感染情况进行调查。方法根据NCBI发表的SV（gi：9627219）基因组序列设计引物,建立RT-PCR方法,对方法的特异性和灵敏性进行验证,并用该方法检测60份灰仓鼠的肺脏样本。结果建立的SV RT-PCR方法显示有较好的敏感性和特异性：以仙台病毒为模板扩增产生197 bp的单一目的条带,经测序比对与NCBI数据库中SV相关序列的一致率为98%,而以猴副流感病毒（SV5）、犬瘟热病毒、小鼠肺炎病毒、呼肠孤病毒III型及腮腺炎病毒为对照无任何条带产生;能检出的SVcDNA最低浓度是96.8 ng/mL;用该方法检测60份灰仓鼠,SV的感染率为3.33%（2/60）。结论建立的SV RT-PCR方法可用于实验类啮齿动物动物SV的常规检测,自然条件下灰仓鼠感染SV的问题不容忽视。     

Virus Meets Liposome

Abstract

Sendai virus was the first virus to encounter liposomes. Gangliosides when incorporated into liposomes act as Sendai virus receptors even at 0–4°C. When receptor-containing liposomes are incubated with virus at 37°C, they envelop the virus. At 37°C liposomes also fuse with Sendai virus membrane.

Virus binding initially involves weak adhesion, which may allow the virus to “browse” the cell, and which is followed by adhesion strengthening. MicrogrΔpHs of Sendai virus fusion with liposomes after one minute at 37°C indicate that fusion occurs at the very curved leading edge of the region of the liposome enveloping virus. A model of fusion is proposed that emphasizes the role of the curvature and membrane tension in this localized region of “host” membrane. The curvature assists close approach and destabilizes the outer monolayer. The proposed intermediates are consistent with the “stalk” hypothesis.     

Molecular Weight Determination of Sendai RNA by Dimethyl Sulfoxide Gradient Sedimentation

The molecular weight of the large RNA of Sendai virus has been determined by sedimentation analysis in sucrose gradients containing 99% dimethyl sulfoxide (DMSO) to be 2.3 × 10⁶. Sendai RNA recovered from 99% DMSO was found to cosediment with nondenatured Sendai RNA at 46 to 48s in ordinary sucrose gradients. The molecular weight value of 2.3 × 10⁶ is considerably smaller than the estimates of 6 × 10⁶ to 7 × 10⁶ determined under nondenaturing conditions, suggesting a unique structure for Sendai RNA.     

Self-Annealing of Sendai Virus RNA

Both complementary strands are found in 50S Sendai virion RNA. 50S Sendai virion RNA has been shown to consist of unequal amounts of a single population of plus and minus strands by annealing studies.     

Transient Inhibition of Polyoma Virus Synthesis by Sendai Virus (Parainfluenza I) II. Mechanism of the Interference by Inactivated Virus

The mechanism of the transient inhibition of polyoma virus synthesis by betapropiolactone-inactivated Sendai virus was studied. Polyoma virus early functions did not appear to be affected, although deoxyribonucleic acid (DNA) and structural protein synthesis were inhibited 60 and 35% respectively. The inhibition of macromolecular synthesis was not sufficient to account for the 90% inhibition of infectious progeny formation. Encapsidation of polyoma DNA into mature virions appears to be completely inhibited after superinfection by beta-propiolactone-inactivated Sendai virus. Ultraviolet irradiation of live or beta-propiolactone-inactivated Sendai virus preparations abolishes the interfering capacity, indicating that a functional Sendai virus ribonucleic acid molecule is the interfering component.     

Evidence that the Low Molecular Weight RNA Associated with Chicory Yellow Mottle Virus is a Satellite

Chicory yellow mottle virus, ringspot strain (CYMV-RS), supports the replication of a low molecular weight RNA (0.17 × 10⁶ daltons) associated with CYMV-T (type stain).
Competition hybridization experiments revealed lack or nucleotide sequence homology between 0.17 × 10⁶ mol. wt. RNA (Sat RNA) and CYMV-RS genomic RNAs, and partial homology (33 %) with CYMV-T genomic RNAs. However, such apparent partial homology can be due to contamination of CYMV-T genomic RNAs with a multimeric form of Sat RNA having a similar molecular weight. On this account the hypothesis that CYMV-T Sat RNA is a true satellite RNA becomes tenable.