Ultrastructural Studies of Barley Mesophyll Cella lnfected with Barley Yellow Mosaic Viruses

lexuous filamentous, rod-shaped particles, and laminated, pinwheel inclusions were observed in the mesophyll cells of the barley plants naturally infected with barley yellow mosaic viruses. These virus particles had a length of 480–920 nm and a width of 10–20 nm. In addition, bundles of filamentous structures which consisted of many particles with more 2000 nm in length were found in the leaves of the infected barley plants. The ultrastructural alterations of the infected mesophyll cells were rather conspicuous. The cytoplasmic matrix was lost seriously, and the chloroplast membrane system was destroyed. The cristae and matrix of the mitochondrium were decreased and some of them became vacuoles. The endoplasmic reticulum (ER) expanded teristic membranous network structures occurred in the cytoplasm of infected cells. The virus particles were often associated at one end with ER and with the membranes of network structures. The nucleus, membrane and wall of ceils also had somewhat variation.     

Ourmia melon virus, a virus from Iran with novel properties

A virus associated with a mosaic disease in melons in the Ourmia district in northern Iran was mechanically transmissible to a wide range of test plants but was not transmitted using aphids, the whitefly Trialeurodes vaporariorum or the mite Tetranychus urticae. Its rather stable particles somewhat resembled those of both geminiviruses and alfalfa mosaic virus; they were 18·5 nm in mean width, parallel-sided, and of several discrete lengths, 30 nm and 37 nm being the shortest and commonest lengths. Both ends of all particles were sharply triangular in profile. The particles contained linear single-stranded RNA of three sizes, estimated as 0·91,0·35 and 0·32, all × 10⁶ molecular weight, and two coat proteins of 26·3 and 23·3 × 10³ estimated molecular weight. The virus, named Ourmia melon virus, appears to be the first described representative of a new virus group.     

Host range, purification and properties of potato virus T

Potato virus T (PVT) infected nine species of tuber-bearing Solanum, most of them symptomlessly, and as a rule was transmitted through the tubers to progeny plants: two genotypes of S. tuberosum ssp. andigena were not infected. The virus was also transmitted by inoculation with sap to 37 other species in eight plant families. Chenopodium amaranticolor is useful as an indicator host, C quinoa as a source of virus for purification, and Phaseolus vulgaris as a local-lesion assay host; the systemic symptoms in Datura stramonium, Nicotiana debneyi and in these three species are useful for diagnosis. Attempts to transmit PVT by aphids failed, but the virus was transmitted through seed to progeny seedlings of four solanaceous species, and from pollen to seed of S. demissum. PVT was purified by clarifying sap with n-butanol or bentonite, followed by precipitation with polyethylene glycol, differential centrifugation and sedimentation in a sucrose density gradient. Purified preparations had an E260/E280 ratio of 1.18 and contained a single infective component with a sedimentation coefficient of 99 S. This component consisted of flexuous filamentous particles of about 640 times 12 nm that showed a characteristic substructure when stained with uranyl acetate. The virus particles contained a single species of infective single-stranded RNA, of molecular weight 2–2 times 106 daltons, and a single species of polypeptide of molecular weight about 27 000 daltons. PVT is serologically related to apple stem grooving virus but not to four other common potato viruses with flexuous filamentous particles. Apple stem grooving virus and PVT cause similar symptoms in several hosts, but also differ somewhat in host range and symptomatology. Apple stem grooving virus did not infect potato, caused additional symptoms in C. quinoa also infected with PVT, and its particles did not show the structural features specific to PVT. The two viruses are considered to be distinct. The cryptogram of PVT is R/1:2–2/(5): E/E: S/C.     

Viruspartikel im Siebröhrensaft von Cucumis sativus L. nach Infektion durch das Cucumisvirus 2 A

Summary Sieve tube sap obtained from cucumber plants infected by Cucumis Virus 2 A induced the typical mosaic disease when it was inoculated into healthy plants of the same species. The infectious factor could not be removed by dialysis or by treatment with phosphodiesterase. Therefore it is improbable that the virus is transported in the sieve tubes as low molecular units or as an unprotected RNA. Rod shaped particles (345×23 m) were found in the infectious sieve tube sap when it was investigated by electron microscopy. The same particles could be found in the sap extracted from infected leaves, but never in sieve tube sap obtained from healthy plants. There is reason to suppose that the Cucumis Virus 2 A is transported in the sieve tubes as complete particles.

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Einige Ergebnisse dieser Arbeit sind Teil einer Dissertation der Technischen Hochschule Darmstadt (D 17, 1964).     

Characterization of Caper Latent Virus

A virus with filamentous particles c. 662 nm in length, distantly serologically related to HelVS was isolated from caper (Capparis spinosa) in Southern Italy and characterized as a member of the carlavirus group. Virus particles have asedimentation coefficient of 168 S and a buoyant density in CsCl of 1.31 g × cm^?3. They are constituted by a single protein species with a molecular weight of 35.700 which encapsidates a single species of single stranded RNA with the apparent size of 9100 nucleotides. This RNA was infectious constituting the whole viral genome. Virus particles either scattered or in aggregates but no specific cytopathological alterations were seen in infected cells. This carlavirus proved to infect caper symptomlessly and was often isolated in nature from plants without apparent signs of infection. For this reason, the name of caper latent virus (CapLV) is suggested for it. It is also suggested that CapLV be identical with caper vein banding virus, a tentative, member of the carlavirus group superficially described in 1970 from Southern Italy.     

Further studies on seed transmission of broad bean stain virus and Echtes Ackerbohnenmosaik -Virus in field beans (Vicia faba)

Broad bean stain virus (BBSV) and Echtes Ackerbohnenmosaik-Virus (EAMV) were detected in the seed coat and embryo sac fluid of immature seeds from infected field beans (Viciafaba minor) by inoculation to Phaseolus vulgaris; BBSV was also detected in immature embryos. The proportion of seeds infected with either virus decreased during maturation. The viruses were transmitted to seedlings as often through fully ripened seeds from which the seed coats had been removed as through intact seeds. Both viruses were detected in pollen from infected plants, but in glasshouse tests only BBSV was transmitted through pollen to seeds. Delaying fertilization in plants infected with BBSV or EAMV seemed not to affect seed transmission of either virus. In glasshouse tests BBSV was transmitted more often through seeds from plants that were inoculated before flowering than during flowering, and was not transmitted through seeds from plants inoculated after flowering; EAMV was transmitted only through seeds from plants inoculated before flowering. In tests on seed from naturally infected plants BBSV was transmitted more often through seeds from plants that developed symptoms before flowering than during flowering. Both viruses were seed-borne in all cultivars tested and there was no marked difference in the frequency of transmission of either virus among the spring-sown cultivars most common in Britain. Both viruses persisted in seed for more than 4 yr.     

Characterization and translation of transmissible gastroenteritis virus mRNAs.

Three protein species were identified in purified transmissible gastroenteritis virus particles (strain Purdue). They are thought to represent constituents of the peplomer (E2; molecular weights of 280,000 and 240,000), the envelope (E1; molecular weights of 28,000, 31,500, and 33,000), and the nucleocapsid (N; molecular weight of 48,000). In infected cells, proteins with molecular weights of 195,000 (E2), 48,000 (N), and 28,000 (E1) were detected. Tunicamycin, an inhibitor of N glycosylation, prevented the appearance of polypeptides with molecular weights of 195,000 and 28,000 in infected cells; instead, proteins with molecular weights of 160,000 and 25,000 were observed. One minor and five major mRNA species were detected in porcine cells after infection. Their size was determined to be 23.6 kilobases (kb) (RNA1), 8.4 kb (RNA3), 3.8 kb (RNA4), 3.0 kb (RNA5), 2.6 kb (RNA6), and 1.9 kb (RNA7). The RNAs were translated in vitro. RNA7 was shown to code for the N protein. Although complete separation of RNA6 could not be achieved, it was shown to encode an unglycosylated (molecular weight of 25,000) precursor of E1 (molecular weight of 28,000). RNA4 was translated into a nonstructural protein with a molecular weight of 24,000. Translation of RNA3 resulted in proteins with molecular weights of 250,000 and 130,000 and smaller molecules which could be precipitated with a monoclonal antibody directed against E2.     

大麦黄花叶病毒侵染的大麦叶肉细胞超微结构研究

在自然感染大麦黄花叶病毒的大麦叶肉细胞中可见线条状和杆状的病毒粒体以及风轮状内含体。这些病毒的长度一般为480—920nm,宽为lo—20nm。此外,还观察到一种由许多病毒组成的堆束状结构,这种病毒的直径为13nm 左右,长度可达2000nm 以上。感病叶肉细胞的超微结构变化是相当明显的。在病害严重的细胞中,细胞基质丧失严重;叶绿体膜系统破坏;线粒体的嵴和基质减少;内质网膨大或断裂,小泡大量出现,病毒粒体的一端往往与内质网联结在一起,特征性膜性网络结构在感染的细胞质中形成。细胞核和细胞膜也发生了变化。     

Host Effect on Arbovirus Replication: Appearance of Defective Interfering Particles in Murine Cells

Serial passage of Semliki Forest virus (SFV) in chicken embryo cells had little effect on SFV yield; however, high multiplicity infection of murine cells with one of the late passage pools (passage 9 SFV) resulted in a virus yield 10- to 20-fold lower than that obtained with earlier passage virus and 80-fold lower than the corresponding yield in chicken cells. This effect was accompanied by a striking decrease in the levels of 42S and 26S RNA and by increased proportions of a small single-stranded viral RNA (molecular weight, 9 x 10(5)) and of a low-molecular-weight replicative form. There was also a reduction in the number of specific membranous structures previously associated with the group A arbovirus replication complex. These results suggested that passage 9 SFV contained defective interfering particles which were detected more readily after one passage in a murine indicator host cell. Identical results were obtained with two different murine cell lines: one a leukemia virus-free clone of AKR cells and the other JLS-V9 cells chronically infected with Rauscher leukemia virus. Host production of RNA tumor virus particles apparently did not affect arbovirus replication.     

Ultrastructural events during hypersensitive response of potato cv. Rywal infected with necrotic strains of potato virus Y

Potato plants cv. Rywal with hypersensitivity gene Ny-1 infected with PVY^N or PVY^NTN reacted in local necroses 3 days after infection. Potato virus Y (PVY) particles were found in epidermis, mesophyll, phloem and xylem cells in inoculated leaves. Noncapsidated virus particles (without capsid protein) were observed already 10 h after infection by using electron microscopy in situ. Capsid protein on one terminus of noncapsidated virus particles was located 5 days after inoculation with the use of immunogold labeling method. Whereas cytoplasmic inclusions were observed for the first time 24 days after infection during hypersensitive response. Ultrastructural studies showed that ER may take part in PVY RNA replication and capsidation of Potyvirus particles. Observed cytopathological changes and virus particles indicate that cell nucleus and mitochondrion might participate in PVY life cycle. During hypersensitive response PVY particles were found in plasmodesmata as well as in phloem and xylem.     

Replication of Sindbis Virus V. Polyribosomes and mRNA in Infected Cells

Cells infected with wild-type Sindbis virus contain at least two forms of mRNA, 26S and 49S RNA. Sindbis 26S RNA (molecular weight 1.6 x 10(6)) constitutes 90% by weight of the mRNA in infected cells, and is thought to specify the structural proteins of the virus. Sindbis 49S RNA, the viral genome (molecular weight 4.3 x 10(6)), constitutes approximately 10% of the mRNA in infected cells and is thought to supply the remaining viral functions. In cells infected with ts2, a temperature-sensitive mutant of Sindbis virus, the messenger forms also include a third species of RNA with a sedimentation coefficient of 33S and an apparent molecular weight of 2.3 x 10(6). Hybridization-competition experiments showed that 90% of the base sequences in 33S RNA from these cells are also present in 26S RNA. Sindbis 33S RNA was also isolated from cells infected with wild-type virus. After reaction with formaldehyde, this species of 33S RNA appeared to be completely converted to 26S RNA. These results indicate that 33S RNA isolated from cells infected with either wild-type Sindbis or ts2 is not a unique and separate form of Sindbis RNA.     

Detection of strains of African cassava mosaic virus by nucleic acid hybridisation and some effects of temperature on their multiplication

DNA probes, made by cloning double-stranded forms of each of the genome parts (DNA-1 and DNA-2) of the Kenyan type isolate of African cassava mosaic virus (ACMV-T), reacted strongly with extracts from Nicotiana benthamiana plants infected with ACMV-T, or with Angolan or Nigerian isolates that are closely serologically related to the type isolate. However, only the DNA-1 probes reacted with extracts of TV. benthamiana infected with a Kenyan coast isolate (ACMV-C), which is serologically less closely related to ACMV-T. DNA-1 and DNA-2 probes also reacted with extracts of mosaic-affected Angolan cassava plants, including some which have not yielded ACMV particles detectable by immunosorbent electron microscopy and from which virus isolates have not been transmitted to TV. benthamiana. These anomalous plants, unlike other naturally infected cassava plants, showed mosaic symptoms on all their leaves which, however, contained only traces of virus particle antigen detectable by enzyme-linked immunosorbent assay. They contain isolates of ACMV that are probably defective for particle production. ACMV-T particles accumulated optimally in N. benthamiana at 20–25°C. At 30°C fewer particles, which apparently had a slightly greater specific infectivity, were produced. At 15°C, considerable quantities of virus particle antigen, virus DNA and virus particles were produced but the particles were poorly infective, and the few that could be purified contained an abnormally large proportion of polydisperse linear DNA molecules, and fewer circular molecules than usual. Angolan isolates, whether particle-producing or not, likewise replicated better in cassava plants at 23 °C than at 30 °C. In contrast, ACMV-C attained only very low concentrations in N. benthamiana, but these were greater at 30 °C than at 23°C.     

Purification and properties of blackberry chlorotic ringspot, a new virus species in subgroup 1 of the genus Ilarvirus found naturally infecting blackberry in the UK

A mechanically transmissible virus was isolated from Bedford Giant blackberry plants showing chlorotic mottling and ringspot symptoms growing in Scotland. It infected several herbaceous test plants, many of them symptomlessly. This virus was also transmitted to several Rubus species and cultivars by graft inoculation with scions from the field‐infected Bedford Giant plant. Most grafted plants were infected symptomlessly, but Himalaya Giant blackberry and the hybrid berry Tayberry developed symptoms similar to those in the infected Bedford Giant plant. In the sap of infected Chenopodium quinoa, the virus lost infectivity when diluted 10^?4 but not 10^?3, after 6 h and 48 h when kept at 20°C and 4°C, respectively, but was infective for more than 8 days when kept at ?15°C. Preparations of purified virus from infected C. quinoa or spinach sedimented as three major nucleoprotein components and consisted of quasi‐isometric particles that varied in size from 24 to 32 nm in diameter and that were not penetrated by negative stain. Such virus particle preparations contained a major polypeptide of ca 28 kDa and three single‐stranded RNA species of estimated size 3.2, 2.8 and 2.1 kb. The complete sequence of the largest RNA (RNA 1, 3478 nt) and the partial sequence of the other RNAs (1863 and 2102 nt long, respectively) were determined and compared with sequences in databases. These findings, together with the biological and biochemical properties of this virus, indicate that it should be regarded as a distinct species in subgroup 1 of the genus Ilarvirus even though it was serologically unrelated to existing members of this subgroup. The virus showed a very distant serological relationship with prune dwarf virus (PDV) but differed significantly from it in the amino acid sequence of its coat protein, experimental host range and symptomatology and was unrelated to PDV at the molecular level. The virus, tentatively named blackberry chlorotic ringspot virus, is therefore a newly described virus and the first ilarvirus found naturally infecting Rubus in the UK.     

Mechanical Transmission, Purification and Properties of an Isolate of Maize Stripe Virus from Venezuela

A Venezuelan isolate of maize stripe virus (MStpV) was successfully transmitted mechanically and by the leafhopper Peregrinus maidis from field infected plants to sweet cv. Iochief. After purification of maize infected with MStpV, fine spiral filamentous particles about 4 nm in diameter and with variable lengths were consistently associated with a nucleoprotein band present in CsCl or Cs₂SO₄ isopycnic gradients. Purified preparations exhibited a typical nucleoprotein absorption spectrum with a maximum at 260–263 nm and a minimum at 240–243 nm and a 260–280 ratio of 1.38. The density of the nucleoprotein in CsCl gradients was estimated at 1.29 g/ml. The sedimentation coefficient was calculated at 62 S. The nucleoprotein consisted of 5 % single stranded RNA and a capsid protein of molecular weight 33.500 daltons. Large quantities of non-capsid proteins were isolated from infected tissue with a molecular weight of 17.500 and 16.500 daltons. Peregrinus maidis, injected with purified MStpV preparation failed to transmit the disease to healthy plants. However, they were infectious when injected with clarified infected plant sap. Antisera against capsid and non-capsid proteins from MStpV-Florida strain reacted positively with the Venezuelan antigens.     

Production of Virus by Mammalian Cells Transformed by Rous Sarcoma and Murine Sarcoma Viruses

Cultured cells of mammalian tumors induced by ribonucleic acid (RNA)-containing oncogenic viruses were examined for production of virus. The cell lines were established from tumors induced in rats and hamsters with either Rous sarcoma virus (Schmidt-Ruppin or Bryan strains) or murine sarcoma virus (Moloney strain). When culture fluids from each of the cell lines were examined for transforming activity or production of progeny virus, none of the cell lines was found to be infectious. However, electron microscopic examination of the various cell lines revealed the presence of particles in the rat cells transformed by either Rous sarcoma virus or murine sarcoma virus. These particles, morphologically similar to those associated with murine leukemias, were found both in the extracellular fluid concentrates and in whole-cell preparations. In the latter, they were seen budding from the cell membranes or lying in the intercellular spaces. No viruslike particles were seen in preparations from hamster tumors. Exposure of the rat cells to (3)H-uridine resulted in the appearance of labeled particles with densities in sucrose gradients typical of virus (1.16 g/ml.). RNA of high molecular weight was extracted from these particles, and double-labeling experiments showed that this RNA sedimented at the same rate as RNA extracted from Rous sarcoma virus. None of the hamster cell lines gave radioactive peaks in the virus density range, and no extractable high molecular weight RNA was found. These studies suggest that the murine sarcoma virus produces an infection analogous to certain "defective" strains of Rous sarcoma virus, in that particles produced by infected cells have a low efficiency of infection. The control of the host cell over the production and properties of the RNA-containing tumorigenic viruses is discussed.     

Biosynthesis of virus-specific proteins in cells infected with infectious bursal disease virus and their significance as structural elements for infectious virus and incomplete particles.

It has previously been shown that infectious bursal disease virus is a naked icosahedral particle with a diameter of about 60 nm and a genome consisting of two segments of double-stranded RNA (Müller et al., J. Virol. 31:584-589, 1979). One of the two major structural polypeptides (molecular weight, 40,000) of this virus could not be found in lysates of infected cells; it is derived from a precursor polypeptide demonstrable inside the cells in relatively large quantities and seems to be processed during virus assembly or later. The precursor molecule is regularly present in the infectious virus particle (buoyant density, 1.33 g/ml) in minor proportions, but it represents an outstanding structural element of incomplete noninfectious particles ("top components"; buoyant density, 1.29 g/ml) which contain viral RNA. This type of incomplete particles is mainly produced by chicken embryo fibroblasts in contrast to lymphoid cells from the bursa of Fabricius. Precursor-product relationships also seem to exist in the biosynthesis of the other viral polypeptides. In contrast to some other viruses with a segmented double-stranded RNA genome, none of the structural proteins of infectious bursal disease virus is appreciably glycosylated.     

Changes in physiology and biochemistry of mottle streak virus infected finger millet plants

A significant reduction in the growth parameters viz., plant height, number of tillers, number of productive tillers, leaves, leaf area, 1000 grain weight and grain yield were observed in the mottle streak virus infected finger millet plants compared to healthy finger millet plants. The germination and vigour of seedlings from the seeds of infected plants were reduced. Physiological changes in finger millet as a result of virus infection were investigated. The chlorophyll pigments ‘a’ and ‘b’ as well as total chlorophyll were reduced due to mottle streak infection. The virus infection led to increased total sugar, starch, soluble protein and phenol contents. The mineral metabolism of infected plants showed a reduction in nitrogen, phosphorus, potassium, magnesium, calcium and iron.     

Transmission Studies with Cucumber Green Mottle Mosaic Virus

Cucumber green mottle mosaic virus may spread in bottlegourd under field conditions through soil contaminated with infected plant debris followed by contact. No seed transmission was noticed in bottlegourd (Lagenaria siceraria) or vegetable marrow (Cucurbita pepo) although pollen grains and cotyledons from infected bottlegourd flowers or seeds, respectively, contained negliginle amounts of virus. Cucumber leaf beerles (Raphidopalpa fevicollis) are probable vectors since their regurgitated fluid and excretes contained infective virus particles. No vector fungi were found in the soil around infected bottlegourd plants.     

An umbraviral protein,involved in long-distance RNA movement,binds viral RNA and forms unique,protective ribonucleoprotein complexes

Umbraviruses are different from most other viruses in that they do not encode a conventional capsid protein (CP); therefore, no recognizable virus particles are formed in infected plants. Their lack of a CP is compensated for by the ORF3 protein, which fulfils functions that are provided by the CPs of other viruses, such as protection and long-distance movement of viral RNA. When the Groundnut rosette virus (GRV) ORF3 protein was expressed from Tobacco mosaic virus (TMV) in place of the TMV CP [TMV(ORF3)], in infected cells it interacted with the TMV RNA to form filamentous ribonucleoprotein (RNP) particles that had elements of helical structure but were not as uniform as classical virions. These RNP particles were observed in amorphous inclusions in the cytoplasm, where they were embedded within an electron-dense matrix material. The inclusions were detected in all types of cells and were abundant in phloem-associated cells, in particular companion cells and immature sieve elements. RNP-containing complexes similar in appearance to the inclusions were isolated from plants infected with TMV(ORF3) or with GRV itself. In vitro, the ORF3 protein formed oligomers and bound RNA in a manner consistent with its role in the formation of RNP complexes. It is suggested that the cytoplasmic RNP complexes formed by the ORF3 protein serve to protect viral RNA and may be the form in which it moves through the phloem. Thus, the RNP particles detected here represent a novel structure which may be used by umbraviruses as an alternative to classical virions.     

Dissemination and detection of peanut clump virus in groundnut seed

Experiments were done to assess the role of seed-transmission in the dissemination of peanut clump virus (PCV) in groundnut (Arachis hypogea L.), and the usefulness of enzyme-linked immunosorbent assay (ELISA) for detecting the virus in infected groundnut seed. The virus was present in 7.5% of seedling progeny from infected plants and could be detected in 16.5% of the seeds by ELISA. When groundnut seeds were grown in a field contaminated by the virus, it was shown that by roguing the infected plants, only 0.1% of the seeds from the remaining plants contained the virus. It was also established that the level of contamination of seeds by the virus was inversely proportional to the seed size.