Characterization of Sendai virus persistently infected L929 cells and Sendai virus pi strain: recombinant Sendai viruses having Mpi protein shows lower cytotoxicity and are incapable of establishing persistent infection

It is commonly accepted that the temperature-sensitive phenotype of Sendai virus (SeV) persistently infected cells is caused by the M and/or HN proteins. Expression level of the L, M, HN, and V proteins is extremely low in L929 cells persistently infected with SeVpi (L929/SeVpi cells) incubated at 38°C. The HN protein quickly disappears in L929/SeVpi cells following a temperature shift up to 38°C, and pulse-chase experiments show that the Lpi, HNpi, and Mpi proteins are unstable at 38°C. Following a temperature shift either upward or downward, M protein is translocated into the nucleus and then localizes to the perinuclear region. None of virus-specific polypeptides are detected in the cells primarily infected with SeVpi and incubated at 38°C and virus proteins are not pulse-labeled at 38°C, indicating that temperature-sensitive step is at an early stage of infection. The Mpi protein is transiently located in the nucleus of the SeVpi primarily infected cells. Recombinant SeVs possessing the HNpi or/and Mpi proteins are not temperature-sensitive. The HN protein is expressed at very low levels and the F protein localizes to the perinuclear region in rSeV(Mpi)-infected cells incubated at 38°C for 18 h. rSeVs having the Mpi protein exhibit lower cytotoxicity and are incapable of establishing persistent infection. Amino acid 116 of the Mpi protein is related to the nuclear translocation and lower cytopathogenesis, whereas aa183 is involved in the interaction between M protein and viral glycoproteins.     

Molecular characterization of Drosophila cells persistently infected with Flock House virus

Little is known about the molecular determinants causing and sustaining viral persistent infections at the cellular level. We found that Drosophila cells persistently infected (PI) with Flock House virus (FHV) invariably harbor defective viral RNAs, which are replicated by the FHV RNA-dependent RNA polymerase. Some defective RNAs encoded a functional B2 protein, the FHV suppressor of RNA interference, which might contribute to maintenance of virus persistence. Viral small interfering RNAs (vsiRNAs) of both polarities were detected in PI cells and primarily mapped to regions of the viral genome that were preserved in the isolated defective RNAs. This indicated that defective RNAs could represent major sources of vsiRNAs. Immunofluorescence analysis revealed that mitochondria and viral proteins are differentially distributed in PI cells and lytically infected cells, which may partly explain the reduction in infectious viral progeny. Our results provide a basis for further investigations of the molecular mechanisms underlying persistent infections.     

Viral genome synthesis in BHK 21 cells persistently infected with Sendai virus

We have carried out daily analysis of the viral RNA species replicated by nucleocapsids present in the cytoplasm of two different BHK 21 cell lines persistently infected with Sendai virus. At each day of analysis (both before and after crises of cytopathology, and during long periods of stable growth) DI particle size RNA was the major species of viral RNA replicated within these nucleocapsids. The molar ratio of DI RNA to standard virus (50 S) RNA species within intracellular nucleocapsids was always extremely high (from 10/1 to 340/1). Thus, there is no evidence for cyclic variations in relative predominance of standard virus and DI nucleocapsids in populations of these persistently infected cells, although “cycling” could occur at the individual cell level at infrequent intervals. Furthermore, challenge of persistently infected cultures with standard Sendai virus or incubation at 33° also failed to significantly decrease the ratio of DI nucleocapsids to standard virus nucleocapsids. It was also found that multiple DI RNA species are present (most are not resolvable by sucrose gradient analysis), and that these evolve with time—some arising and increasing with time, while others are outcompeted. No selective advantage for DI RNA of any particular size was observed. Finally, by measuring the total amount of nucleocapsids present in these persistently infected cells (as estimated by level of NP protein in purified nucleocapsids), and the degree of synthesis of viral nucleocapsid (as determined by [³H]uridine incorporation in the presence of actinomycin D), we found that the rate of viral genome replication was 30- to 40-fold lower in the persistently infected cells than it was in St acutely infected cells. These findings may indicate that the accumulated nucleocapsids in persistently infected cells are built up over a period of many weeks of slow synthesis, although turnover times for NP protein and RNA of nucleocapsids have not yet been determined in persistently infected cells.     

Contribution of the leader sequence to homologous viral interference among Sendai virus strains

Sendai viruses (SeV) derived from persistent infection have a capacity to interfere with co-infected wild-type virus. Here we showed that interference was also caused by the laboratory strains Z and Nagoya. The leader mutations A(20)U and A(24)U related to viral adaptation from mice to chicken eggs significantly affected the capacity for viral interference, especially through genome amplification. Furthermore, recombinant SeV that possessed the mutations A(34)G and G(47)A, which are commonly found in the leader sequence of persistent infection-derived SeV strains, had an increased capacity for interference. Viral replication of human parainfluenza viruses 1, 2, and 3, but not the mumps virus or Newcastle disease virus, was suppressed by co-infection of a persistent infection-derived SeV strain, suggesting suppression of closely related human paramyxoviruses. These results indicate that homologous interference is partly dependent on the promoter sequence and further suggest involvement of promoter activity for genome amplification related to host factors in viral interference.     

Evaluation of a virus derived from MDCK cells infected persistently with influenza A virus as a potential live-attenuated vaccine candidate in the mouse model

A temperature-sensitive mutant virus unable to replicate at 38 degrees C was recovered from passage 189 (IVpi-189) of Madin-Darby canine kidney cells infected persistently with influenza A. Immunofluorescent staining of the IVpi-189 virus-infected cells revealed disrupted transport of the matrix (M) 1 protein into the nucleus at non-permissive temperatures, resulting in retention of the nucleoprotein (NP) in the nucleus. Upon comparison with the parental influenza A E61-24-P15 strain used to establish persistent infection, amino acid exchanges were found in the M1 protein of IVpi-189 virus; arginine to glutamine at position 72 and threonine to alanine at position 139. When mice were inoculated intranasally with IVpi-189 virus, virus growth in the lungs was restrained and terminated rapidly. Prior intranasal inoculation with only a small dose of IVpi-189 virus induced humoral and cellular immune responses and protected mice against subsequent virulent virus challenge. These results indicate that IVpi-189 virus, an avirulent temperature-sensitive mutant, is a promising candidate for use as a live-attenuated vaccine.     

Recombinant Sendai viruses with L1618V mutation in their L polymerase protein establish persistent infection, but not temperature sensitivity

The Sendai virus pi strain (SeVpi) isolated from cells persistently infected with SeV shows mainly two phenotypes: (1) temperature sensitivity and (2) an ability of establishing persistent infection (steady state). Three amino acid substitutions are found in the Lpi protein and are located at aa 1088, 1618, and 1664. Recombinant SeV(Lpi) (rSeV(Lpi)) having all these substitutions is temperature sensitive and is capable of establishing persistent infection (steady state). rSeVs carrying the fragment containing L1618V show both phenotypes. rSeV(L1618V), in which leucine at aa 1618 is replaced with valine, has the ability of establishing persistent infection, but is not a temperature-sensitive mutant, indicating that the ability of a virus to establish persistent infection can be separated from temperature sensitivity. The amino acid change at 1618(L-->V) coexisting with aa 1169 threonine is required for acquirement of a temperature-sensitive phenotype. Three amino acid substitutions are also found in the Ppi protein, but rSeV(Ppi) does not show these phenotypes.     

Markedly reduced severity of Dengue virus infection in mosquito cell cultures persistently infected with Aedes albopictus densovirus (AalDNV)

AalDNV-infected C6/36 cells serially passaged for over 10 weeks showed a decline in percentage of anti-AalDNV-positive cells (APC) from an initial 92% to approximately 20%. Cultures of persistent APC were indistinguishable from uninfected cultures by direct microscopy but most stained cells from early APC passages had enlarged nuclei with eosinophilic inclusions, while late APC passages had few and naive cells none. Super challenge of persistent APC cultures did not increase percentage APC and supernatants from persistent APC cultures gave low APC (40%) in naive C6/36 cell cultures. When challenged with dengue virus serotype 2 (DEN-2), naive C6/36 cells showed severe cytopathic effects (CPE) and high mortality within 4 days, as did early passage APC cultures. Remarkably, DEN-2 infections in persistent APC cultures were much less severe, being characterized by reduced DEN-2 infection percentage, retarded DEN-2 virion production, no CPE and no significant mortality. Reasons for rapid reduction in APC and resistance to superinfection upon serial passage remain unproven but may relate to production of AalDNV-defective interfering particles (DIP) by molecular mechanisms still open to speculation. More difficult to explain is cross-protection against DEN-2-induced mortality seen in persistent APC cultures. However, by comparison to work on shrimp viruses, we speculate that this may involve blockage of viral-triggered apoptosis. The phenomena described raise questions regarding the potential for persistent infections by unknown viruses to confound experimental results with insect cell lines.     

仙台病毒 Tianjin 株缺陷干扰颗粒体内外诱导大鼠脑胶质瘤细胞凋亡的研究

目的探讨仙台病毒Tianjin株缺损干扰颗粒（ defective interfering particles ,DI颗粒）体内外诱导大鼠脑胶质瘤细胞C6凋亡的作用。方法将不同滴度仙台病毒Tianjin株DI颗粒分别与大鼠脑胶质瘤细胞C6作用不同时间,以培养基作为阴性对照、完整病毒作为阳性对照,通过DNA片段琼脂糖凝胶电泳、TUNEL染色、AnnexinⅤ-FITC/PI标记流式细胞仪分析等检测细胞凋亡情况。建立大鼠皮下胶质瘤模型,通过测量肿瘤大小观察DI颗粒抑瘤作用,病理切片HE染色观察肿瘤组织病理变化,TUNEL法检测肿瘤组织细胞凋亡情况。结果 C6细胞在体外经DI颗粒诱导后, DNA片段琼脂糖凝胶电泳呈阶梯状;流式细胞仪及TUNEL检测显示,DI颗粒组与完整病毒组细胞凋亡率明显增高,且呈时间-剂量依赖型。动物实验结果显示,DI颗粒和完整病毒均可明显抑制肿瘤生长;肿瘤组织病理切片HE染色显示DI颗粒组和完整病毒组瘤结节内瘤细胞较少;TUNEL原位细胞凋亡检测显示DI颗粒组和完整病毒组凋亡细胞明显增加,以上结果与阴性对照组比较差异均有统计学意义（P＜0．01）。结论仙台病毒Tianjin株DI颗粒在体内外均能引起大鼠脑胶质瘤C6细胞凋亡,且呈时间-剂量依赖型,提示DI颗粒有辅助治疗脑胶质瘤的可能性。     

Paramyxovirus Sendai virus C proteins are essential for maintenance of negative-sense RNA genome in virus particles

The Sendai virus (SeV) C proteins are a nested set of four accessory proteins, C', C, Y1, and Y2, encoded on the P mRNA from an alternate reading frame. The C proteins are multifunctional proteins involved in viral pathogenesis, inhibition of viral RNA synthesis, counteracting the innate immune response of the host cell, inhibition of virus-induced apoptosis, and facilitating virus-like particle (VLP)/virus budding. Among these functions, the roles for pathogenesis and counteracting host cell interferon (IFN) responses have been studied extensively, but the others are less well understood. In this paper, we found that the C proteins contributed in many ways to the efficient production of infectious virus particles by using a series of SeV recombinants without one or more C protein expression. Knockout of both C' and C protein expression resulted in reduced virus release despite higher viral protein synthesis in the cells. Interestingly, for the viruses without C' and C, or all four C protein expression, non-infectious virions containing antigenomic RNAs were produced predominantly compared to genomic RNA-containing infectious virions, due to aberrant viral RNA synthesis. Our results demonstrate for the first time that the C proteins regulate balance of viral genome and antigenome RNA synthesis for efficient production of infectious virus particles in the course of virus infection.     

Increase of virus yields and releases of Borna disease virus from persistently infected cells

Borna disease virus grows to low titres in persistently infected cells with an infectious particle to cell ratio of 0.01 to 0.05. Inclusion of n-butyrate in the growth medium enhances infectivity yields up to 1 log. This effect is time and concentration dependent. In hypertonic medium with an excess of NaCl, KCl or Na2SO4 up to 50% of the total infectious virus yield is released from the cells. Released supernatant virus (buoyant density in sucrose rho = 1.22 g/cm3) is more heat stabile than cell-bound virus (rho = 1.18 g/cm3). The access to cell-free (released) virus opens new possibilities for the characterization of this neurotropic agent.     

Experimental inoculation of the adult rat testis with Sendai virus: effect on testicular morphology and leukocyte population

BACKGROUND: Surprisingly little is known about the interactions between viruses and the male uro-genital tract. These are important, as viral testicular orchitis, induced by mumps or human immunodeficiency virus (HIV) infection for example, can lead to sterility. Moreover, semen is an essential vector in the propagation of sexually transmissible viral diseases. Here, we studied the effects of testicular infection with Sendai virus, a virus related to mumps virus, on the cellular distribution of viral particles and on testicular morphology, with particular attention to the testicular leukocyte population. METHODS: At 5, 9, 11 or 24 h post-injection of Sendai virus through the scrotum, the testes were fixed for morphological and immunohistological studies. Localization of virus particles and numeration of leukocytes were performed using specific antibodies and morphological criteria. RESULTS: As early as 5 h post-injection, a rapid and massive infiltration of leukocytes was observed in the interstitial tissue. The peritubular cell layer and the most external part of the basal portion of the seminiferous tubules were altered. The virus was diffusely located within the interstitial tissue 9 h following the injection whereas, after 24 h, viral proteins were restricted to the cytoplasm of infiltrated leukocytes. The number of leukocytes increased with time post-injection. Thus, 24 h post-injection, CD3+ T-cell number was 3-fold higher, ED1+ monocyte number was 4-fold higher and polynuclear cell number was 600-fold higher than in the control testes (P<0.001 all observations). In contrast, the population of resident macrophages was unaffected by Sendai virus. CONCLUSIONS: Testicular viral infection causes inflammation including rapid recruitment of leukocytes. The experiments presented here provide a model for further studies on the etiopathology of viral orchitis, in particular that caused by mumps virus.     

Sequence-function analysis of the Sendai virus L protein domain VI

The large (about 2200 amino acids) L polymerase protein of nonsegmented negative-strand RNA viruses (order Mononegavirales) has six conserved sequence regions (“domains”) postulated to constitute the specific enzymatic activities involved in viral mRNA synthesis, 5′-end capping, cap methylation, 3′ polyadenylation, and genomic RNA replication. Previous studies with vesicular stomatitis virus identified amino acid residues within the L protein domain VI required for mRNA cap methylation. In our recent study we analyzed four amino acid residues within domain VI of the Sendai virus L protein and our data indicated that there could be differences in L protein sequence requirements for cap methylation in two different families of Mononegavirales — rhabdoviruses and paramyxoviruses. In this study, we conducted a more comprehensive mutational analysis by targeting the entire SeV L protein domain VI, creating twenty-four L mutants, and testing these mutations for their effects on viral mRNA synthesis, cap methylation, viral genome replication and virus growth kinetics. Our analysis identified several residues required for successful cap methylation and virus replication and clearly showed the importance of the K-D-K-E tetrad and glycine-rich motif in the SeV cap methylation. This study is the first extensive sequence analysis of the L protein domain VI in the family Paramyxoviridae, and it confirms structural and functional similarity of this domain across different families of the order Mononegavirales.     

Recovery of a Sendai virus variant with temperature-sensitive hemolytic activity from persistently infected cells from mouse brain

Summary A persistently infected cell line designated MB/Sen_AS was established by cultivation of mouse brain cells from four-day-old C3H mice infected intracerebrally at birth with 10⁶ PFU of Sendai virus, strain 52. After 5 passages, 0.16 per cent of Sendai₅₂ antiserum (containing two 50 per cent plaque reducing doses/ml of serum) was introduced into the culture medium. The addition of antiserum was accompanied by a rise in cell-associated viral antigen from a level of 5 per cent antigen positive cells to 100 per cent demonstrable by both intracellular and membrane immunofluorescence.A variant of Sendai₅₂ virus, designated Sendai_AS, was recovered from MB/Sen_AS by inoculation of supernatant medium into chick embryos. Infection of chick embryos at 37° C was abortive. Fifty per cent or less of chick embryos infected at dilutions 10^–1 to 10^–9 yielded detectable virus. Hemagglutination (HA) was weak but could be improved by trypsinization of allantoic fluids. Neuraminidase (NA) activity was barely detectable. Hemolysis (HE) was absent. Propagation of Sendai_AS virus at 33° C showed no change from weak HA and NA activities but HE activity was now apparent which was temperature sensitive. Mortality of infected chick embryos increased to 100 per cent. HE activity and lethality for chick embryos was thermolabile at 45° C.With 3 Figures     

C and V proteins of Sendai virus target signaling pathways leading to IRF-3 activation for the negative regulation of interferon-beta production

We here report a molecular basis for downregulation of interferon (IFN)-beta production by V and C proteins of Sendai virus (SeV). The infection of HeLa cells with SeV poorly induced IFN-beta even if the expression of C/C' was disrupted. In contrast, when the expression of C/C'/Y1/Y2 or V/W was disrupted, SeV infection strongly induced IFN-beta production and significantly activated the interferon regulatory factor (IRF)-3 pathway. The independent expression of C or V inhibited the double-stranded (ds) RNA- or Newcastle disease virus (NDV)-induced activation of IRF-3 and NF-kappa B, as well as the IFN-beta promoter. This inhibitory effect was also observed when Y1, Y2, or a C-terminal half fragment (aa 85-204) of C was independently expressed. Phosphorylation and homodimer formation of IRF-3 were suppressed not only in cells infected with SeV capable of expressing both C/C'/Y1/Y2 (or Y1/Y2) and V/W, but also in HeLa cells constitutively expressing Y1. These results suggest that C, Y1, Y2, and V block signaling pathways leading to IRF-3 activation to downregulate IFN-beta production.     

Masking of the contribution of V protein to Sendai virus pathogenesis in an infection model with a highly virulent field isolate

Sendai virus V protein is not essential for virus replication in cultured cells but is essential for efficient virus replication and pathogenesis in mice, indicating that the V protein has a luxury function to facilitate virus propagation in mice. This was discovered in the Z strain, an egg-adapted avirulent laboratory strain. In the present study, we reexamined the function of Sendai virus V protein by generating a V-knockout Sendai virus derived from the Hamamatsu strain, a virulent field isolate, which is an appropriate model for studying the natural course of Sendai virus infection in mice. We unexpectedly found that the V-knockout virus propagated efficiently in mice and was as virulent as the wild-type virus. Switching of the functionally important V unique region demonstrated that this region of the Hamamatsu strain was also functional in a Z strain background. It thus appears that the V protein is nonsense in a field isolate of Sendai virus. However, the V protein was required for virus growth and pathogenesis of the Hamamatsu strain in mice when the virulence of the virus was attenuated by introducing mutations that had been found in an egg-adapted, avirulent virus. The V protein therefore seems to be potentially functional in the highly virulent Hamamatsu strain and to be prominent if virus replication is restricted.     

AGS and other tissue culture cells can unknowingly be persistently infected with PIV5; a virus that blocks interferon signalling by degrading STAT1

Whilst screening various cell lines for their ability to respond to interferon (IFN), we noted that in comparison to other tissue culture cells AGS tumour cells, which are widely used in biomedical research, had very low levels of STAT1. Subsequent analysis showed that the reason for this is that AGS cells are persistently infected with parainfluenza virus type 5 (PIV5; formally known as SV5), a virus that blocks the interferon (IFN) response by targeting STAT1 for proteasome-mediated degradation. Virus protein expression in AGS is altered in comparison to the normal pattern of virus protein synthesis observed in acutely infected cells, suggesting that the AGS virus is defective. We discuss the relevance of these results in terms of the need to screen cell lines for persistent virus infections that can alter cellular functions.     

Pathogenic potentials of glycoprotein C-negative syncytial mutants from rabbit T cells infected persistently with herpes simplex virus type 1

Human T cell lymphotropic virus type I (HTLV-I)-transformed T cells of rabbits were infected persistently with Herpes simplex virus type 1 (HSV-1) strain KOS. These infected cells yielded syncytial mutants, either glycoprotein C (gC)-negative or -positive, which predominated over and replaced the wild-type virus in a long-term culture for 2 years. An alignment of nucleotide sequences showed multiple mutations in glycoprotein B (gB) and gC genes of these mutants, which are or may be responsible for the mutant phenotypes. One of four mutants analyzed produced extensively large syncytia and possessed point mutations within the cytoplasmic domain of gB. All four mutants possessed multiple point mutations in gC and two possessed single insertions which resulted in a frame shift, leading to the premature termination of the gC polypeptide chain. The supernatant of the 2-year culture of cells infected persistently, containing only gC-negative syncytial mutants, induced encephalitic symptoms in B/Jas inbred rabbits, when injected intravenously. One gC-negative syncytial isolate from an encephalitic lesion, together with those from the culture supernatant, were examined for pathogenic potential in vitro and in vivo. All these mutants were more cytotoxic and more susceptible to complement inactivation than the parental virus, and could infect and replicate in adrenal glands when injected intravenously into rabbits. Invasion into the central nervous system appeared to be blocked at the portal of entry, the adrenal gland, i.e., none exhibited neuroinvasive potential by itself. Syncytial gC-negative mutants could thus be pathogenic in rabbits.     

Recruitment of Alix/AIP1 to the plasma membrane by Sendai virus C protein facilitates budding of virus-like particles

Sendai virus (SeV) is unique in that one of the viral accessory proteins, C, enhances budding of virus-like particles (VLPs) formed by SeV matrix protein M by physically interacting with Alix/AIP1. C protein itself does not have the ability to form VLPs, while M protein provides viral budding force, like other enveloped viruses. Here we show that SeV C protein recruits Alix/AIP1 to the plasma membrane (PM) to facilitate VLP budding. SeV M-VLP budding is sensitive to overexpression of a dominant-negative (DN) form of VPS4A only in the presence of the C proteins, which is able to recruit Alix/AIP1 to the PM. Our results indicate that SeV M and C proteins play separate roles in the budding process: M protein drives budding and C protein enhances the efficiency of the utilization of cellular MVB sorting machinery for efficient VLP budding.