Characterization of Maize Iranian Mosaic Virus and Comparison with Hawaiian and Other Isolates of Maize Mosaic Virus (Rhabdoviridae)

Maize Iranian mosaic virus (MIMV) was characterized and compared with isolates of Maize mosaic virus (MMV, genus Nucleorhabdovirus, family Rhabdoviridae) in insect transmission, cytopathology and ultrastructure of infected maize cells, virion proteins and serologically. MIMV is naturally transmitted by Ribautodelphax notabilis, a delphacid planthopper, in Iran. In this study, another planthopper, Peregrinus maidis, vector of MMV, transmitted MIMV with an estimated efficiency of 0.4–1.6% following feeding on MIMV‐infected maize plants and 64% following injection of MIMV into the hemolymph, suggesting that P. maidis gut tissues largely blocked MIMV transmission. MIMV and MMV‐HI (Hawaii) induced similar cytopathologies in cells of infected maize leaves, with virions budding through inner nuclear and endoplasmic reticulum membranes. In thin sections, virions of MIMV were significantly shorter than those of MMV‐HI. Sodium dodecyl sulphate polyacrylamide gel electrophoresis analysis of virions of MIMV, MMV‐HI, MMV‐CR (Costa Rica) and MMV‐FL (Florida) yielded six proteins of which four were identified as the putative G, N, P and M proteins of plant rhabdoviruses. The N, P and M proteins of MIMV migrated faster in gels than those of the MMV isolates indicating a lower molecular weight, whereas the bands corresponding to the G proteins migrated similarly for both viruses. Polyclonal antibodies to MMV‐HI failed to react with virions of MIMV in enzyme‐linked immunosorbent assay (ELISA) and with MIMV proteins in Western blots. In contrast, these antibodies reacted strongly with MMV‐HI and MMV‐FL virions in ELISA and with MMV‐HI, MMV‐CR and MMV‐FL proteins in Western blots. Further, in ELISA, polyclonal antibodies to MMV‐MR (Mauritius) reacted weakly with MIMV virions but strongly with MMV‐HI and MMV‐FL virions. Thus, it is concluded that MIMV is a new virus of the Nucleorhabdovirus genus that may be distantly related to MMV.     

Mouse pancreas involvement in murine hepatitis virus infection]

After intraperitoneal inoculation with mouse hepatitis virus (MHv) into mice, the excretory cells of the pancreas showed a marked vacuolar degeneration concomitantly with hepatitis. MHV-specific antigen was evidenced in the cytoplasm of infected cells. Electron microscopy revealed a number of virions within the matrix, spaces of the endoplasmic reticulum and areas of focal cytoplasmic necrosis. The virus titer of the pancreas was equal or superior to that of the liver at least in early stage of infection.     

Functional Differences of Dyes in Inducing Respiratory Immunogenicity by Azo-, Thiazole-, Quinoline-, Reactive-, and Naphthol-Dye-Inactivated Sendai Viruses

The prophylactic effects by mouse nasal inoculation of 31 kinds of organic dye-inactivated Sendai viruses were investigated by contact exposure experiment that used mouse nasally infected with 10^5,8 EID₅₀, immunofluorescent examination of the entire respiratory tract, and check of rise of serum HI titer postexposure. The relative merits of the dye-structures for inciting nasal immunogenicity were determined. Of 14 azo-dye-inactivated vaccines, only azo blue- and amido black 10B treated ones brought about nearly complete protection, while the other 5 dye-groups provided partial protection and the remaining 7 dye-groups the least protection. Of 6 thiazole dye-vaccines, primuline-, thioflavine S-, and thioflavine T-vaccines induced complete or almost complete protection, and the others moderate or the least protection. With 3 quinolinevaccines, both pinacyanol- and quinaldine red-inactivated ones provided complete protection, but not with quinoline blue-vaccine. Of 4 reactive dye-vaccines, both cibacron brilliant yellow 3G-P-and reactive blue 4-treated ones brought about nearly complete protection, but the remaining 2 vaccines induced regional infection. Nevertheless, all 4 naphthol group (AS, AS-BS, AS-BI, and AS-MX)-treated vaccines yielded complete or almost complete protection. The thirteen most effective vaccine groups suppressed marked rise of high or low serum HI titers developed through nasal vaccination postexposure. In short, specified dyestuffs having a great affinity for cellulosic fibers, evidently incited mucosal immunogenicity, probably by major union of the dyes to viral core ribose.     

Hemagglutination Inhibition with Arboviruses: Relationship Between Titers and Source of Erythrocytes

Antigens for Grand Arbaud, Hazara, and California arboviruses were able to agglutinate goose and either dog, hamster and guinea pig, or hamster red blood cells (RBC) to the same titer at the same pH; in hemagglutination-inhibition (HI) tests, titers for homologous and related sera were the same with these different types of RBC or occasionally one dilution higher with the mammalian cells. Antigens for St. Louis encephalitis and Eastern equine encephalitis viruses required use of lower antigen dilutions with human, guinea pig, and hamster RBC than with goose RBC. The results of comparative HI testing with these latter antigens and types of RBC indicate that HI titer is not directly related to the antigen dilution used with different types of RBC.     

Efficacy of an Inactivated Porcine Parvovirus (PPV) Vaccine under Field Conditions

Dose response experiments were carried out by vaccinating groups of seronegative gilts (7 months of age) and groups of gilts with residual maternal serum antibodies to PPV (5 months of age). PPV vaccines containing different amounts of inactivated virions were used. Vaccinations were carried out twice with 3 weeks intervals. It was demonstrated, that a single vaccination even with a vaccine with low antigen content elicited an antibody response to PPV in seronegative gilts. The titer values increased after the 2nd vaccination. When the gilts had residual maternal serum antibodies at the time of vaccination the antibody response was generally lower. In some animals the titer values decreased after the 1st vaccination, but except for 2 gilts vaccinated with vaccines with a low antigen content an increase of titer values followed after the 2nd vaccination. During a field trial performed in a herd with enzootic PPV infection all the gilts were vaccinated with PPV vaccine before mating. Blood samples were examined for HI antibodies before and after vaccination and at weaning time of each of the resulting 5 litters. In total 24 batches of gilts comprising 326 animals mated during a 2 year period were examined. It was demonstrated, that the applied vaccine preparations used under field conditions gave a relatively high and long lasting antibody response, even when the gilts were vaccinated as early as at about 5 months of age.     

Regulation of SV40-induced cell division and tumor antigen by dibutyryl adenosine 3′-5′-monophosphate

Simian virus 40 (SV40) induces cell division in microcultures of sparsely plated nongrowing mouse BALB/3T3 cells during acute infection at moderate multiplicities of infection (MOI = 10–100). The infected cells are killed when a MOI of 1,000 is used. SV40 tumor (T) antigen is synthesized in the infected cells, but viral DNA, virion antigen, and progeny virions are not synthesized (abortive infection). The addition of exogenous dibutyryl adenosine 3′-5′-monophosphate (dbcAMP) at the time of infection stimulates the SV40-induced cell division at all MOI and inhibits SV40-induced cell death at high MOI. The percentage of T antigen-positive cells, as monitored by immunofluorescence, is also increased by the addition of dbcAMP at the time of infection. This regulation of SV40-induced cell division and T antigen formation by exogenous dbcAMP occurs within the first 6 hr after infection at 37° C and is dependent upon both the MOI and the concentration of added dbcAMP. The addition of dbcAMP to productively infected TC7 monkey cells has little effect on the SV40-induced cell death or T antigen formation.     

Infectious hepatitis A virus particles produced in cell culture consist of three distinct types with different buoyant densities in CsCl.

Although hepatitis A virus (HAV) released by infected BS-C-1 cells banded predominantly at 1.325 g/cm3 (major component) in CsCl, smaller proportions of infectious virions banded at 1.42 g/cm3 (dense HAV particles) and at 1.27 g/cm3 (previously unrecognized light HAV particles). cDNA-RNA hybridization confirmed the banding of viral RNA at each density, and immune electron microscopy demonstrated apparently complete viral particles in each peak fraction. The ratio of the infectivity (radioimmunofocus assay) titer to the antigen (radioimmunoassay) titer of the major component was approximately 15-fold greater than that of dense HAV particles and 4-fold that of light HAV particles. After extraction with chloroform, the buoyant density of light and major component HAV particles remained unchanged, indicating that the lower density of the light particles was not due to association with lipids. Light particles also banded at a lower density (1.21 g/cm3) in metrizamide than did the major component (1.31 g/cm3). Dense HAV particles, detected by subsequent centrifugation in CsCl, were indistinguishable from the major component when first banded in metrizamide (1.31 g/cm3). However, dense HAV particles recovered from CsCl subsequently banded at 1.37 g/cm3 in metrizamide. Electrophoresis of virion RNA under denaturing conditions demonstrated that dense, major-component, and light HAV particles all contained RNA of similar length. Thus, infectious HAV particles released by BS-C-1 cells in vitro consist of three distinct types which band at substantially different densities in CsC1, suggesting different capsid structures with varied permeability to cesium or different degrees of hydration.     

Combined Fluorescent-Antibody and Electron Microscopy Study of Marek''s Disease Virus-Infected Cell Culture

Duck embryo fibroblast (DEF) and chicken embryo fibroblast (CEF) cultures infected with Marek's disease virus were studied by combined fluorescent antibody and electron microscopy techniques. In both DEF and CEF cultures, cells containing immunofluorescent (IF) antigen also contained herpesvirus particles; conversely, cells lacking this antigen lacked herpesvirus particles. Two morphologically distinct IF antigens were detected in the cytoplasm. (i) A granular antigen in the perinuclear region was brightly stained with the conjugated antibody. This antigen was composed of a granular mass of osmiophilic material and did not contain virions. (ii) A diffuse antigen, present throughout the cytoplasm of infected cells, was less brightly stained. The area of the cell with the highest concentration of this antigen contained small vesicles, folded membranes, and fine electron-dense granules. Naked virions were occasionally seen in these areas. A diffuse nuclear IF antigen was occasionally seen in infected cells. This antigen was often separated from the nuclear membrane and the nucleolus by a clear margin. The intranuclear IF antigen was composed of a fine granular aggregate and naked herpesvirus particles which were randomly distributed throughout the nucleus. Viral capsids in antibody-treated cells were coated with fine filamentous material.     

Monensin inhibits the processing of herpes simplex virus glycoproteins, their transport to the cell surface, and the egress of virions from infected cells.

HEp-2 cells or Vero cells infected with herpes simplex virus type 1 were exposed to the ionophore monensin, which is thought to block the transit of membrane vesicles from the Golgi apparatus to the cell surface. We found that yields of extracellular virus were reduced to less than 0.5% of control values by 0.2 microM monensin under conditions that permitted accumulation of cell-associated infectious virus at about 20% of control values. Viral protein synthesis was not inhibited by monensin, whereas late stages in the post-translational processing of the viral glycoproteins were blocked. The transport of viral glycoproteins to the cell surface was also blocked by monensin. Although the assembly of nucleocapsids appeared to be somewhat inhibited in monensin-treated cells, electron microscopy revealed that nucleocapsids were enveloped to yield virions, and electrophoretic analyses showed that the isolated virions contained immature forms of the envelope glycoproteins. Most of the virions which were assembled in monensin-treated cells accumulated in large intracytoplasmic vacuoles, whereas most of the virions produced by and associated with untreated cells were found attached to the cell surface. Our results implicate the Golgi apparatus in the egress of herpes simplex virus from infected cells and also suggest that complete processing of the viral envelope glycoproteins is not essential for nucleocapsid envelopment or for virion infectivity.     

水稻矮缩病毒昆明分离物抗血清制备及免疫捕捉PCR检测

由水稻矮缩病毒(Rice dwarf virus,RDV)引起的水稻矮缩病害,最早由日本报道,随后在东南亚等国以及我国的福建、云南等南方稻区普遍发生,云南主要发生于中部及南部地区[1]。水稻在苗期至分蘖期感病后,植株矮缩,分蘖增多,叶片浓绿,僵直,出现白斑,生长后期病稻不能抽穗结实,在暴发流行年份可以引起水稻的严重减产。RDV在分类上属于呼肠孤病毒科(Reoviridae)植物呼肠孤病毒属(Phytoreovirus)成员,病毒粒子为正十二面体球形结构,直径约为69.3nm,无刺突,无脂蛋白外膜包被,具有双层的蛋白衣壳[2]。病毒基因组由12条双链RNA片段组成,其中S8编…     

Antibody estimation by indirect complement fixation test for foot-and-mouth disease in cattle.

Antibody against foot-and-mouth disease (FMD) virus was measured by the indirect complement fixation (ICF) test. For this test serum samples were collected from cattle experimentally infected with FMD virus of O, A and Asia 1 types, as well as cattle infected in the field. Two types of antigen were used. One was antigen derived from infected lingual epithelial culture prepared by Frenkel's method with each type of the virus. The other was antigen derived from the lingual epithelium of cattle infected by virus inoculation. ICF antibody began to be dectected about 4 5 days after inoculation. It reached a maximum titer 10 14 days after inoculation, remaining at this titer for about a week or two, and then decreased gradually. It was, however, detectable even 63 days after inoculation. The rise and fall of ICF antibody was parallel with that of neutralizing antibody, although that antibody was always lower in titer than this. ICF antibody was detected type-specifically from cattle infected experimentally and naturally. These results indicated that the ICF test was available for the routine serological diagnosis and epizootiological investigation and research.     

Rescue of SV40 following transfection of TC7 cells with cellular DNAs containing complete and partial SV40 genomes

Summary Infectious SV40 virions could be rescued from permissive TC7 cells within one to three subcultures following cotransfection with two cellular DNAs, each containing a complementary portion of the SV40 genome. SV40 virions could also be rescued by transfection of TC7 cells with cellular DNAs from a variety of SV40 transformed cells containing complete genome equivalents but not from cells containing subgenomes alone or defective genomes. Infectious virus was not rescued if the transfecting DNA species was treated with DNAase or if the DEAE-dextran pretreatment of the recipient cells was omitted.deceased     

猪流感病毒分离鉴定

用非免疫鸡胚从我国上海、福建、湖北分离到3株猪流感病毒,分别命名为SSH1、SFJ1和SHB1。SIV分离株第5代病毒液对0．7％豚鼠红细胞的血凝活性分别1：2^8、1：2^7和1：2^8,与H3亚型标准血清血凝抑制价1：2^8、1：2^7和1：2^8,但不能被鸡新城疫阳性血清所抑制。纯化的病毒在电镜下观察,可见到猪流感典型的病毒粒子。病毒液接种于小白鼠,可表现出临床症状,剖杀后可观察到病毒性肺炎。猪体回归试验,可表现出临床症状和病理变化,从肺脏中可分离到病毒并且RT-PCR也可检测到病毒相应的基因片段。从纯化的病毒中提取RNA,进行RT-PCR,可扩增出预期的条带。     

Transfer of scrapie prion infectivity by cell contact in culture

BACKGROUND: When a cell is infected with scrapie prions, newly synthesized molecules of the prion protein PrP(C) are expressed at the cell surface and may subsequently be converted to the abnormal form PrP(Sc). In an experimental scrapie infection of an animal, the initial innoculum of PrP(Sc) is cleared relatively rapidly, and the subsequent propagation of the infection depends on the ability of infected cells to convert uninfected target cells to stable production of PrP(Sc). The mechanism of such cell-based infection is not understood. RESULTS: We have established a system in dissociated cell culture in which scrapie-infected mouse SMB cells are able to stably convert genetically marked target cells by coculture. After coculture and rigorous removal of SMB cells, the target cells express PrP(Sc) and also incorporate [35S]methionine into PrP(Sc). The extent of conversion was sensitive to the ratio of the two cell types, and conversion by live SMB required 2500-fold less PrP(Sc) than conversion by a cell-free prion preparation. The conversion activity of SMB cells is not detectable in conditioned medium and apparently depends on close proximity or contact, as evidenced by culturing the SMB and target cells on neighboring but separate surfaces. SMB cells were killed by fixation in aldehydes, followed by washing, and were found to retain significant activity at conversion of target cells. CONCLUSIONS: Cell-mediated infection of target cells in this culture system is effective and requires significantly less PrP(Sc) than infection by a prion preparation. Several lines of evidence indicate that it depends on cell contact, in particular, the activity of aldehyde-fixed infected cells.     

The Skin-Reactive Antigens of Mycoplasma pneumoniae

Guinea pigs experimentally infected with Mycoplasma pneumoniae or immunized with the organism in combination with Freund's complete adjuvant developed a delayed hypersensitive skin reaction following on intradermal injection of the M. pneumoniae antigen. The amount of protein necessary to produce the delayed skin reaction was as low as 0.01 μg. When the sonicated whole cells were extracted with aqueous acetone, the delayed skin reactivity was found mostly in the acetone insoluble (lipid-depleted) fraction. On the other hand, the lipid fraction which was isolated by a chloroform–methanol extraction of the acetone-soluble fraction and had a high titer of complement-fixing activity, exhibited little delayed skin reactivity. The lipid-depleted antigens as the whole cell antigens produced delayed skin reactivities in human patients.     

Protease-induced infectivity of hepatitis B virus for a human hepatoblastoma cell line.

The human hepatoblastoma cell line HepG2 produces and secretes hepatitis B virus (HBV) after transfection of cloned HBV DNA. Intact virions do not infect these cells, although they attach to the surface of the HepG2 cell through binding sites in the pre-S1 domain. Entry of enveloped virions into the cell often requires proteolytic cleavage of a viral surface protein that is involved in fusion between the cell membrane and the viral envelope. Recently, we observed pre-S-independent, nonspecific binding between hepatitis B surface (HBs) particles and HepG2 cells after treatment of HBs antigen particles with V8 protease, which cleaves next to a putative fusion sequence. Chymotrypsin removed this fusion sequence and did not induce binding. In this study, we postulate that lack of a suitable fusion-activating protease was the reason why the HepG2 cells were not susceptible to HBV. To test this hypothesis, virions were partially purified from the plasma of HBV carriers and treated with either staphylococcal V8 or porcine chymotrypsin protease. Protease-digested virus lost reactivity with pre-S2-specific antibody but remained morphologically intact as determined by electron microscopy. After separation from the proteases, virions were incubated with HepG2 cells at pH 5.5. Cultures inoculated with either intact or chymotrypsin-digested virus did not contain detectable levels of intracellular HBV DNA at any time following infection. However, in cultures inoculated with V8-digested virions, HBV-specific products, including covalently closed circular DNA, viral RNA, and viral pre-S2 antigen, could be detected in a time-dependent manner following infection. Immunofluorescence analysis revealed that 10 to 30% of the infected HepG2 cells produced HBV antigen. Persistent secretion of virus by the infected HepG2 cells lasted at least 14 days and was maintained during several reseeding steps. The results show that V8-digested HBV can productively infect tissue cultures of HepG2 cells. It is suggested that proteolysis-dependent exposure of a fusion domain within the envelope protein of HBV is necessary during natural infection.     

Separation and Characterization of Soluble Adenovirus Type 9 Components

Four different soluble components of adenovirus type 9 (Rosen's group II) were identified. These were a complete hemagglutinin (HA), an incomplete HA, components carrying group-specific complement-fixing (CF) antigen, and components identified only by their hemagglutination-inhibition (HI) antibody consuming capacity and antigen activity in CF tests with an antiserum against complete HA. The complete HA sedimented relatively rapidly. It was composed of 12 pentons (vertex capsomers plus projections) aggregated into the form of a pentagonal dodecahedron. The length of the projections was about 12 to 13 mmu. Thus they appeared longer than the corresponding structures of types 3 and 11, but shorter than those of types 4 and 5. The rate of sedimentation of complete HA of type 9 was intermediate to those of the complete HA of types 3 and 11. The incomplete HA sedimented together with components carrying group-specific CF antigen, but could be separated from those by anion-exchange chromatography. Two different antigens were present in incomplete HA. One could absorb a group-specific hemagglutination-enhancing antibody, and was sensitive to treatment with trypsin. The other antigen could absorb the type-specific HI antibody and was not destroyed by trypsin. In addition to the incomplete HA, a separate population of more slowly sedimenting components showed a capacity to absorb HI antibody. These components could also be identified in CF tests when an antiserum against complete HA was applied. The incomplete HA, group-specific CF antigen, and slowly sedimenting HI antibody absorbing components are suggested to represent isolated penton, hexon, and fiber components, respectively.     

Host Influence on the Antigenic Composition of the Kilham Rat Virus

The Kilham rat virus (RV) was found to vary in infectivity and antigenic characteristics when propagated in two different host systems. Both cross hemagglutination-inhibition (HI) and cross virus-neutralization tests revealed that a nonreciprocal or one way cross exists between RV propagated in rat embryo cell cultures (RE-RV) and RV propagated in suckling hamsters (H-RV). Specifically, immune serum to RE-RV inhibited hemagglutination and infectivity by both viruses to the same extent. Immune serum to H-RV, however, exhibited higher HI and neutralization titers to H-RV than to RE-RV. Infectivity studies demonstrated that, although both viruses were able to infect either host, the virus showed a higher infectivity titer for the last host in which it had been propagated. Serological studies indicated that H-RV possesses an antigen(s) not found on the RE-RV. This host-controlled variation did not result after a single passage in the new host, but rather required at least three passages for a complete conversion to occur, and did not appear to result from the incorporation of unaltered host antigens into the virus particle. Solubilization of purified RV propagated in each host with sodium dodecyl sulfate, 2-mercaptoethanol, and urea followed by electrophoresis in polyacrylamide gels indicated that the number of components in the protein of each virus was not the same.     

A 165 kd protein of the herpes simplex virion shares a common epitope with the regulatory protein, ICP4

We have investigated the possibility that immediate-early (IE) protein ICP4 could be a part of herpes simplex virus type 1 (HSV-1) virion particle. Immunodetection with a monoclonal antibody against ICP4 reveals that a component of the virion, migrating at 165 kd, shares a common epitope with this immediate-early protein. Immunolocalization studies on purified virions indicate that the antigen can be detected only in virions without membranes, and is located outside the capsid, most probably in the tegument. Ultrastructural localizations on HSV-1 infected BHK cells extracted with a nonionic detergent confirm that the protein immunoreacting with anti-ICP4 is present in virions.