Resolution of strawberry virus complexes; the isolation and some properties of virus 3

Aphids ( Capitophorus fragariae Theob.) allowed to feed for several days on a strawberry plant with severe crinkle transmitted two viruses. The isolation and properties of one (virus I) have already been described. The other (virus 3) was separated by transferring the aphids to fresh indicators after 24 hr.
Virus 3 was transmitted by aphids which had been allowed to feed on an infected plant for 6 days or more and persisted in the vector for several days. There was some evidence that the virus has a latent period in the vector. The symptoms produced by virus 3 on Fragaria vesca and Royal Sovereign strawberry are described.
On Royal Sovereign, viruses 1 and 3 together produced symptoms of severe crinkle and viruses z and 3 together produced yellow-edge. A form of severe crinkle is thus shown to be caused by a virus complex which can be resolved by means of the vector, and severe crinkle is shown to be etiologically distinct from mild crinkle.     

RESOLUTION OF STRAWBERRY VIRUS COMPLEXES

Strawberry virus 4 produces vein chlorosis and necrosis on strawberry (var. Royal Sovereign) and slight chlorotic spotting on wild strawberry ( Fragaria vesca L.). No vector is known. Virus 5 produces leaf curling and vein necrosis on Royal Sovereign and F. vesca. It is transmitted by strawberry aphids ( Pentatrichopus fragaefolii Cock.) which have fed on an infected plant for 1 hr. or more and persists for about 1 hr. in the vector.
The names strawberry mottle, mild yellow-edge, crinkle, vein chlorosis and leaf-curl virus are proposed for strawberry viruses 1, 2, 3, 4 and 5 respectively.     

Resolution of strawberry virus complexes by means of the aphis vector Capitophorus fragariae Theob

Aphides ( Capitophorus fragariae ) were fed for periods of up to 24 hr. on strawberry plants infected with mild crinkle, severe crinkle or yellow-edge and then transferred to plants of the wild strawberry, Fragaria vesca , or of the cultivated strawberry, variety Royal Sovereign. On F. vesca the symptoms produced were chlorotic speckling, distortion and dwarfing of the leaves, varying in intensity', and on Royal Sovereign scattered, inconspicuous, diffuse, chlorotic spots.
The symptoms from all three sources of infection were similar and were indistinguishable from those of mild crinkle of Harris & King. The virus thus selectively transmitted is tentatively concluded to be the mild crinkle virus.
The virus was transmitted after feeding periods of 1 hr. or more and did not generally persist in the vector for more than 3 hr.     

TRANSMISSION AND HOST-RANGE STUDIES OF STRAWBERRY GREEN-PETAL VIRUS

The virus causing phyllody (virescence) in clover flowers was transferred by Cuscuta subinclusa to Fragaria vesca and Duchesnia indica plants which then produced symptoms of strawberry green-petal disease.
The jassid Euscelis plebejus (Fall.) in several forms, including E. lineolatus Brullé, transmitted green-petal virus from clover to clover, to and from a wide range of other hosts, and from but not to strawberry. Two viruses (or strains) were distinguished, one causing phyllody and the other witches' broom on clover; both were retained for more than 2 months by the vector, in which both had a latent period of about 30 days. Macrosteles viridigriseus (Edwards) also transmitted both viruses.
Variation in symptoms on strawberry plants infected naturally, and experimentally through dodder, suggested that two diseases have previously been grouped under the name 'green petal". It is proposed to distinguish these as ( a ) green petal caused by the virus inducing phyllody in clover, and ( b ) bronze leaf wilt caused by the clover witches' broom virus.     

Detection of plant virus coat proteins on whole leaf blots.

Coat proteins of several different plant viruses were transferred from entire leaves of infected hosts to nitrocellulose membranes in 2 min using a hydraulic laboratory press. Protein transfer was even across the leaf as evidenced by India ink staining of blots. Coat proteins of four different viruses were detected using virus specific IgG. The presence of viral coat proteins was observed as small intense spots whose distribution was irregular and coincided most frequently with the presence of chlorosis on the leaves. Detection was sensitive, and accurately reflected the distribution of virus symptoms across leaves.     

Replication of the Reticuloendotheliosis Virus (Strain T) in Chicken Embryo Cell Culture

Investigations were conducted on the in vitro replication of the reticuloendotheliosis (RE) virus (strain T) in specific-pathogen-free chicken embryo fibroblast (CEF) cultures. Active virus production was detected in the tissue culture fluid 24 hr after infection. When injected into chickens, samples taken 42 hr after infection of the cell cultures killed approximately 50% of the birds at a 1:100 dilution. The RE virus titer remained at this level for 5 days before declining. Cell-free virus preparations from tissue cultures rarely resulted in 100% mortality of the assay birds. The level of cell-associated virus was very low. Evidence that the reticuloendotheliosis was not induced by a mycoplasma was indicated by failure to isolate an organism on PPLO Agar (Difco) and failure of kanamycin or amphotericin B to inhibit multiplication of RE virus in vitro. RE virus appeared to be unrelated to members of the avian leukosis and sarcoma complex. It did not induce resistance in CEF cultures to sarcoma viruses of the A or B subgroup of this complex. Similarly, preinfection of cell cultures with leukosis viruses of the A or B subgroup did not inhibit or reduce the replication of RE virus.     

Depletion of the photosystem II core complex in mature tobacco leaves infected by the flavum strain of tobacco mosaic virus

The flavum strain of Tobacco mosaic virus (TMV) differs from the wild-type (wt) virus by causing strong yellow and green mosaic in the systemically infected developing leaves, yellowing in the fully expanded leaves, and distinct malformations of chloroplasts in both types of infected tissues. Analysis of the thylakoid proteins of flavum strain-infected tobacco leaves indicated that the chlorosis in mature leaves was accompanied by depletion of the entire photosystem II (PSII) core complexes and the 33-kDa protein of the oxygen evolving complex. The only change observed in the thylakoid proteins of the corresponding wt TMV-infected leaves was a slight reduction of the alpha and beta subunits of the ATP synthase complex. The coat proteins of different yellowing strains of TMV are known to effectively accumulate inside chloroplasts, but in this work, the viral movement protein also was detected in association with the thylakoid membranes of flavum strain-infected leaves. The mRNAs of different enzymes involved in the chlorophyll biosynthesis pathway were not reduced in the mature chlorotic leaves. These results suggest that the chlorosis was not caused by reduction of pigment biosynthesis, but rather, by reduction of specific proteins of the PSII core complexes and by consequent break-down of the pigments.     

THE MANNER OF TRANSMISSION OF SOME BARLEY YELLOW-DWARF VIRUSES BY DIFFERENT APHID SPECIES

Some barley yellow-dwarf (BYD) viruses isolated from cereal crops in Great Britain were transmitted by Rhopalosiphum padi , L. and others were not. Sitobion fragariae (Walker), S. avenae (Fabricius), and Metopolophium dirhodum (Walker) all transmitted viruses of both types, but they usually transmitted those of which Rhopalosiphum was a vector less readily than did R. padi. The transmissibility of a virus by a given aphid species was not affected by transmission with another, less efficient, vector species. Neomyzus circumflexus (Buckt.) and Rhopalosiphum maidis (Fitch) transmitted the few viruses with which they were tested.
A few R. padi acquired virus from infected leaves during 30 min. feeding and inoculated healthy seedlings during 15 min. feeding, but the minimum total time taken to acquire and transmit was 10 hr. and 32 hr. were needed for about half the aphids that were able to acquire and transmit virus to do so. This may indicate the existence of a short latent period of the virus in the vector, although the evidence is not conclusive. The times spent on infected plants influenced the results more than those spent on healthy ones; many transmissions occurred with short feeding times on healthy plants so long as the time spent on infected leaves was long, but the reverse was not true. Nymphs of R. padi that moulted after they left infected plants on which they fed long enough to become infective, infected slightly fewer plants than adults fed for the same times.     

Chickpea chlorotic dwarf virus,a new leafhopper-transmitted geminivirus of chickpea in India1

A disease of chickpea in India, characterised by chlorosis, severe stunting and phloem browning, was shown to be caused by a geminivirus. This virus was transmitted by the leafhopper Orosius orientalis from chickpea to chickpea and several other plant species. A method for purification of this virus was devised and a polyclonal antiserum produced. The majority of the purified particles were geminate. The size of the coat protein was shown to be 32 kD and the nucleic acid was shown to be circular ssDNA of 2900 nucleotides. By immunosorbent electron microscopy this virus was shown to be unrelated to the leafhopper-transmitted geminiviruses known to infect dicotyledons such as beet curly top, bean summer death and tobacco yellow dwarf viruses. On the basis of particle morphology, leafhopper transmission, host range and serology this virus was considered to be a new, hitherto undescribed, geminivirus and was named chickpea chlorotic dwarf virus.     

Bioassaying an insect virus on leaves. II. The influence of certain factors associated with the larvae and the leaves

The importance of certain factors which act through the larvae or through the leaves when a virus suspension is bioassayed by applying a known volume in droplets to a leaf of standard size has been investigated. The most critical was the age of the second-instar larvae. In 24 hr their resistance to infection increased significantly. On the other hand, starving the test larvae for 6 hr to assist randomization of factors that influenced the area of treated leaf consumed did not produce a measurable effect on mortality. A 2°C increase in the temperature reduced the incubation period of the disease but produced no effect on the final kill due to the virus. The practical implications of these results are discussed in relation to the bioassay procedure.     

Rapid Detection and Identification of Respiratory Viruses by Direct Immunofluorescence

The use of fluorescein-conjugated antiserum against respiratory syncytial (RS) and parainfluenza 1 and 3 viruses was compared with conventional techniques in the rapid detection of virus in tissue cultures inoculated with pharyngeal specimens known to contain these viruses. Twenty-three specimens were tested: 9 RS, 8 parainfluenza 1, and 6 parainfluenza 3. The fluorescent-antibody technique (FA) detected virus in 52% of the tissue cultures in 24 hr, and, by 72 hr, 22 of the 23 cultures were FA-positive whereas only 5 were positive by conventional techniques. Additionally, conjugated antisera were prepared against herpes simplex, influenza A₂, and adenovirus type 5. All conjugates stained only the homologous virus and were 100- to 10,000-fold more sensitive than conventional techniques in detecting descending dilutions of virus inocula by 24 hr. With the procedures described, several antisera could be conjugated and ready for use within 24 hr. Serum fractionation was by ammonium sulfate precipitation, and with the procedure outlined virtually complete recovery of the globulin fraction and elimination of all of the albumin were accomplished.     

Purification, Properties and Serology of Strawberry Mild Yellow-Edge Virus

Oregon isolate My-18 of strawberry mild yellow-edge virus (SMYEV) was purified by comminution in liquid nitrogen, extraction in 0.1 M phosphate, 0.01 M DIECA, 1 % thioglycollic acid (pH 7.0) and differential and rate-zonal density gradient (dg) centrifugation. The resulting ultraviolet-absorbing dg band (A_{254 nm}), not seen in healthy control preparations, contained isometric, 23 mm-diameter, virus-like particles. The partially purified MY-18 virus was not transmitted to Fragaria vesca by means of membrane-fed or injected Chaetosiphon fragaefolii. MY-18 has an in vivo thermal inactivation point between 45 and 50 °C as determined by feeding C. fragaefolii on detached leaves that had been immersed in water for 10 min at various temperatures. In ELISA, rabbit antisera against MY-18 differentiated between partially purified preparations from root and leaf tissue and between crude root but not crude leaf extracts from healthy and MY-18-infected Fragaria. Our data support the generally held hypothesis that SMYEV is a luteovirus. However, comparative ISEM and ELISA tests failed to reveal any serological releationship between MY-18 and potato leafroll, beet western yellows, legume yellows, pea leafroll, or tobacco necrotic dwarf viruses.     

VIRUSES CAUSING ROSETTE AND OTHER DISEASES IN GROUNDNUTS

From plants with a form of groundnut rosette disease, characterized by discrete areas of green and chlorotic tissue on the leaflets and here designated 'mosaic rosette', a virus was separated that produced only a mild mottle or sometimes a mottle with rare chlorotic flecks. It was separated by leaf grafts, by mechanical inoculation and by Aphis craccivora .
Plants inoculated simultaneously with the mottle virus and normal rosette virus usually developed the mosaic-rosette symptoms. When the mottle virus was introduced 14–35 days before the rosette virus, the plants failed to develop the severe chlorosis of rosette; the mottle virus thus protected the plant from rosette, and this was true whether the rosette virus was inoculated by aphids or by grafting.
Plants showing two other forms of mild mottle were collected in the field; viruses from them were readily transmitted by grafting or by mechanical inoculation, but not by A. craccivara . In plant-protection tests with one of these, it failed to protect plants from developing chlorotic symptoms when later inoculated with the rosette virus, although a form of interaction was evident and the doubly-infected plant was less severely chlorotic and less stunted than one infected with the rosette virus alone.     

SOME EFFECTS OF TANNIC ACID AND OF LEAF EXTRACTS WHICH CONTAIN TANNINS ON THE INFECTIVITY OF TOBACCO MOSAIC AND TOBACCO NECROSIS VIRUSES

The inhibition of infection by tobacco necrosis and tobacco mosaic viruses by tannic acid, and by extracts of raspberry and strawberry leaves, was associated with the precipitation of the viruses. Precipitation and inhibition were reversible, and infective virus was obtained from the precipitate formed between the viruses and tannins. Infectivity was fully restored by diluting mixtures of virus and tannin adequately and partially restored by adding alumina or nicotine sulphate.
Viruses and tannins are thought to form non-infective complexes, in which the virus and tannin components are held together by co-ordinate linkages or hydrogen bonds.
Macerating tobacco leaves infected with tobacco mosaic virus together with raspberry leaves greatly decreased the infectivity of the extracts; adding nicotine sulphate to the mixture of leaves before it was ground increased the infectivity, even though nicotine sulphate alone decreases the infectivity of tobacco mosaic virus. Even in the presence of nicotine sulphate, much of the virus was precipitated by substances from the raspberry leaves.
Extracts of roots of Fragaria vesca plants, infected with a tobacco necrosis virus, were more infective when made by macerating the roots with four times their weight of buffer at pH 8 than when made without buffer. Various methods are suggested for facilitating the transmission of viruses from plants that contain tannin.     

Cell-mediated cytotoxicity against virus-infected target cells in humans. II. Interferon induction and activation of natural killer cells.

The mechanisms by which human lymphocytes lyse virus-infected allogeneic fibroblast cultures were analyzed with particular consideration of the role of anti-viral antibodies and interferon. Human cells infected with viruses were able to induce high levels of interferon upon contact with human lymphocytes. Interferon, whether produced by lymphocytes after direct infection with virus or induced upon exposure of lymphocytes to virus-infected fibroblasts, appeared to be responsible for enhancing the cytotoxic efficiency of the natural killer cell against the infected target. Activation of cytotoxic lymphocytes occurred as early as 6 hr after addition of interferon and increased up to 24 hr. Antibody-dependent cell-mediated cytotoxicity (Ab-CMC) could be easily induced by sensitization of infected target cells with antiviral antibodies and could be detected at 4 hr from the beginning of the cytotoxic test, before the effect of interferon on the natural killer cell was evident. However, the antibody-dependent effector cell was inactive after 4 hr of incubation. F(ab')2 fragments of rabbit anti-human IgG completely inhibited Ab-CMC but did not at all affect the spontaneous cytotoxic activity of the effector cells against virus-infected target.     

SOME EFFECTS OF VIRUS INFECTION ON LEAF WATER CONTENTS OF NICOTIANA SPECIES

Infection with tobacco mosaic virus decreases the water content which detached tobacco leaves attain when kept for 20 hr. in conditions of minimum water stress, and does so more when the plants are kept in light before inoculation than when they are kept in darkness. No such effects of infection during the first day after inoculation were obtained with tobacco leaves infected with either tobacco etch virus or potato virus X , or with Nicotiana glutinosa leaves infected with tobacco mosaic virus. These results, like those showing early effects of TMV on respiration and photosynthesis of tobacco leaves, suggest that inoculation with TMV affects deeper leaf tissues than the epidermis earlier in tobacco leaves than in other leaves, and earlier than other viruses in tobacco leaves.     

Active Oxygen-producing and -scavenging Enzymes in Pepper Leaves Infected with Xanthomonas campestris pv. vesicatoria

Lipoxygenase (LOX), peroxidase (POX), superoxide dismutase (SOD) and catalase (CAT) activities were determined in pepper (Capsicum annuum) leaves infected with Xanthomonas campestris pv. uesicatoria, from 3 to 15 days after inoculation, before symptom appearance and during the development of the disease. Strong Stimulation of LOX and POX activities was observed in infected leaves at an advanced stage of the disease (12–15 days after inoculation), when bacterial water-soaked spots and a slight chlorosis of the inoculated leaf areas were evident and a decrease in chlorophyll content of infected tissue was detected. The infection also induced a significant increase in CAT activity at the day 9 and a decrease in SOD and CAT activities at the day 12. On the basis of the changes observed, uncontrolled production of active oxygen species at advanced stages of infection is hypothesized.     

A single nucleotide change within a plant virus satellite RNA alters the host specificity of disease induction

Some RNA plant viruses contain satellite RNAs which are dependent upon their associated virus for replication and encapsidation. Some cucumber mosaic virus satellite RNAs induce chlorosis on any of several host plants, including either tobacco or tomato. The exchange of sequence domains between cDNA clones of chlorosis-inducing and non-pathogenic satellite RNAs delimited the chlorosis domain for both tobacco and tomato plants to the same region. Site-directed mutagenesis of one nucleotide (149) within this domain changed the host plant specificity for a chlorotic response to satellite RNA infection from tomato to tobacco. Within the chlorosis domain, three conserved nucleotides are either deleted or altered in all satellite RNAs that do not induce chlorosis. Deletion of one of these nucleotides (153) did not affect satellite RNA replication but rendered it non-pathogenic. Thus, two single nucleotides have been identified which play central roles in those interactions between the virus, its satellite RNA and the host plant, and together result in a specific disease state.