Interference Between Tobacco necrosis virus and Turnip crinkle virus in Nicotiana benthamiana

Mixed infections of Nicotiana benthamiana plants by Tobacco necrosis virus (TNV) and Turnip crinkle virus (TCV) exhibited an interference interaction. Accumulation of TNV (+)RNA as well as capsid protein in mixed infection were considerably lower than that of singly infected plants. There were also a slight reduction in the levels of TCV (+)RNA and capsid protein in doubly infected plants, which displayed the concentration of both viruses decreased in dually infected plants. Tissue immunoblot analysis of systemic N. benthamiana leaves infected by TNV and TCV singly or doubly showed the interference between the two viruses in situ, which exhibited the decrease of both viruses in doubly infected leaves although the distribution of them did not change remarkably. These results were consistent with the hybridization analysis of viral genomic RNA and coat protein. Both cross‐protection test and mixed infection of the two viruses confirmed TCV had relatively stronger interference to the infection of TNV. Interference infection by TNV and TCV induced higher increase in the levels of cytochrome pathway respiration and alternative pathway respiration in host plants, especially the latter. Interference often occurred in different strains of one kind of virus or two different closely related viruses in one genus. Our results showed that interference could also occur in different viruses belonging to different genera.     

Induction of resistance in Phaseolus vulgaris L. cv. Lima against some soil-borne fungal pathogens by pre-inoculation with tobacco necrosis virus (TNV) reacting hypersensitivity

Abstract

Tobacco necrosis virus (TNV) was tested to induce systemic acquired resistance (SAR) in Phaseolus vulgaris cv. Lima against three important soil-borne fungal pathogens viz: Rhizoctonia solani, Macrophomina phaseolina and Fusarium oxysporum. Application of TNV as a local infection of seven-day old primary leaves of Phaseolus vulgaris cv. Lima resulted in reduction of the mean disease rating of root-rot and damping-off caused by the tested fungal pathogens. The pre-inoculated plants with TNV showed a significant enhancement in their content of photosynthetic pigments (chlorophyll a, b and carotenoids) compared to those inoculated with fungal pathogens only. The percentage of cell membrane stability and ion leakage of viral-treated plants were significantly increased confirming the healthy cytological status of the treated plants. Results demonstrated that inoculation of the primary leaves of beans with TNV before infection with the fungal pathogens leads to changes in protein patterns and showed differences compared with control and caused the appearance of at least one new protein band compared with only fungal-infected plants. Also, an increase in peroxidase activity emerged in the thickness of the isozymic pattern in addition to the synthesis of new bands which was observed as a result of TNV application before infection with the three fungal pathogens. Induction of the synthesis of a new protein and increasing peroxidase activity in the inoculated plants enhanced the defense system against the target pathogen. The results greatly supported the successful application of TNV in the induction of systemic acquired resistance in P. vulgaris cv. Lima against the fungal pathogens.     

Restricted distribution of potato leafroll virus antigen in resistant potato genotypes and its effect on transmission of the virus by aphids

Enzyme-linked immunosorbent assay was used to measure the concentration of potato leafroll virus (PLRV) antigen in different parts of field-grown secondarily infected plants of three potato genotypes known to differ in resistance to infection. The antigen concentration in leaves of cv. Maris Piper (susceptible) was 10–30 times greater than that in cv. Pentland Crown or G 7445(1), a breeder's line (both resistant). Differences between genotypes in antigen concentration were smaller in petioles and tubers (5–10-fold) and in above-ground stems (about 4-fold), and were least in below-ground stems, stolons and roots (about 2-fold). PLRV antigen, detected by fluorescent antibody staining of tissue sections, was confined to phloem companion cells. In Pentland Crown, the decrease in PLRV antigen concentration in leaf mid-veins and petioles, relative to that in Maris Piper, was proportional to the decrease in number of PLRV-containing companion cells; this decrease was greater in the external phloem than in the internal phloem. The spread of PLRV infection within the phloem system seems to be impaired in the resistant genotypes. Green peach aphids (Myzuspersicae) acquired < 2800 pg PLRV/aphid when fed for 4 days on infected field-grown Maris Piper plants and < 58% of such aphids transmitted the virus to Physalis floridana test plants. In contrast, aphids fed on infected Pentland Crown plants acquired <120 pg PLRV/aphid and <3% transmitted the virus to P. floridana. The ease with which M. persicae acquired and transmitted PLRV from field-grown Maris Piper plants decreased greatly after the end of June without a proportionate drop in PLRV concentration. Spread of PLRV in potato crops should be substantially decreased by growing cultivars in which the virus multiplies to only a limited extent.     

Induction of Systemic Resistance to Tobacco Powdery Mildew by Tobacco Mosaic Virus, Tobacco Necrosis Virus or Ethephon

Local infections of either TMV or TNV in tobacco plants cv. Havana 425 (hypersensitive to TMV) proved effective in inducing systemic resistance to subsequent inoculation with the powdery mildew fungus Erysiphe cichoracearum DC. The proportion of leaf surface invaded by this pathogen and the amount of conidia it produced were both significantly lower in virus inoculated plants than in non-inoculated controls. However, the decrease in sporulation rate was less regularly observed than the reduction in leaf area infected. TMV was more effective than TNV in protecting tobacco plants from powdery mildew. E. cichoracearum is thus added to the list of challenge pathogens to which TMV or TNV are known to induce resistance in the host plants. Necrotic lesions caused to the leaves by local treatment with Ethephon (an ethylene-releasing compound) also conferred to tobacco some degree of systemic resistance to the same fungal pathogen, more frequently visible as a reduction of leaf area invaded. The protection due to the Ethephon lesions was in present experiments less marked than that of TMV. No effects against subsequent powdery mildew infection were obtained when point freeze necrotic lesions were provoked on the plants.     

Characterization of Synergy between Cucumber mosaic virus and Tobacco necrosis virus in Nicotiana benthamiana

Mixed infections of Nicotiana benthamiana plants by Cucumber mosaic virus (CMV) and Tobacco necrosis virus (TNV) exhibit a synergistic interaction and result in symptom enhancement. Accumulation of CMV(+) RNA as well as capsid protein (CP) in mixed infection was considerably higher than that of singly‐infected plants. There was also a slight increase in TNV(+) RNA and CP levels in doubly infected plants. Synergistic infection by CMV‐ and TNV‐induced higher increase in the levels of malonyldialdehyde, hydrogen peroxide (H₂O₂) and more decline in the activities of catalase than singly infected ones. Both peroxidase and superoxide dismutase activities increased rapidly for the first 10 days post inoculation (dpi) in doubly‐infected plants and then declined, whereas the enzyme activities continued to increase after 10 dpi in singly infected plants and had higher enzyme activities in the late stages than that of co‐infected plants. These results suggest that synergistic infection by CMV and TNV produced severes oxidative stress in N. benthamiana plants and the synergy between the two viruses was mutual.     

Chenopodium necrosis: a distinctive strain of tobacco necrosis virus isolated from river water

A distinctive strain of tobacco necrosis virus (TNV) of unknown source was repeatedly isolated from water of the River Avon (Warwickshire) and two of its tributaries (R. Swift and R. Alne) using a technique developed for the concentration and isolation of water-borne bacteriophages. The same strain was isolated from the rivers Cam and Thames and from Lake Esthwaite (Cumbria) together with tomato bushy stunt virus. The TNV strain, designated Chenopodium necrosis (TNV-CN) was mechanically transmissible to C. amaranticolor and C. quinoa in both of which it caused local lesions and systemic infection. TNV-CN caused no infection when inoculated to tobacco (Nicotiana tabacum cv. White Burley) plants. The virus was not adsorbed to soil, could be isolated from leachate of soil in which systemically infected C. quinoa were grown and C. quinoa plants became infected when grown in soil watered with suspensions of the virus. The virus was not transmitted by Myzus persicae but was vectored by the zoospores of a lettuce isolate of Olpidium brassicae. TNV-CN was infective after 10 min at 85 °C., 3 wk at 20 °C and when diluted to 10^-8 but not 10^-9. Purified virus preparations contained c. 26 nm isometric virus particles. TNV-CN contained single-stranded RNA (mol. wt 1·5 × 10⁶) and one protein (mol. wt c. 26·4 × 10³) which co-electrophoresed in polyacrylamide gels with the protein of the D strain of TNV (TNV-D). Analytical centrifugation of TNV-CN indicated a single component virus with the same sedimentation coefficient (s₂₀, w= 115S) and buoyant density (1·385) in a CsCl gradient as those of TNV-D. TNV-CN and TNV-D were indistinguishable serologically.     

Factors affecting aphid acquisition and transmission of soybean mosaic virus

Myzus persicae transmitted soybean mosaic virus (SMV) most efficiently following 30 or 60 s acquisition probes on infected plants. There were no differences in susceptibility to SMV infection of soybean plants 1 to 12 wk old, but symptoms were more severe in plants inoculated when young than when old. Soybeans inoculated between developmental stages R3 and R6 only showed yellowish-brown blotching on one or more leaves. There were no observable differences in the time of appearance or type of symptoms shown by soybean seedlings inoculated either by sap or by aphids; infected plants became acquisition hosts for aphids 5–6 days after inoculation. There was no change in the efficiency with which M. persicae transmitted SMV from source plants up to 18 wk after inoculation. M. persicae transmitted SMV from leaves of field-grown soybeans when plants were inoculated at developmental stages V6, R2, and R3 and tested as sources 57–74 days after inoculation but not from plants inoculated at R5 and tested as sources 14 to 32 days after inoculation. M. persicae acquired SMV from soybean buds, flowers, green bean pods, and unifoliolate, trifoliolate, and senescent leaves. Middle-aged and deformed leaves were better sources of the virus than buds, unfolding and old symptomless leaves. The results are being incorporated into a computer model of SMV epidemiology.     

Occurrence of Tobacco Necrosis Virus in Strawberry Cultivars and Frageria vesca Indicators

Tobacco necrosis virus (TNV) was found occasionally in roots of indicator plants such as UC-4, UC-5 and alpine, commonly used for screening of strawberry virus diseases. The virus was purified and identified as TNV by its host-range, physical properties, electron microscopy and serological tests. The implication of the possible occurrence of TNV in indicator plants on reliable diagnosis of virus disease in strawberry is discussed.     

Virus Infection of Forest Trees by Mechanical Transmission

Abstract Back transmission trials on young forest plants with isolates of purified viruses from the same tree species were performed using different inoculation techniques. Spruce seedlings and willow plants were successfully infected with tobacco necrosis virus (TNV) by the conventional method of mechanical inoculation of virus suspension mixed with celite as abrasive. Cherry leaf roll virus (CLRV) was transmitted to birches only after adding poly-L-orithine (PLO) to the inoculum. The same method was successful with brome mosaic virus (BMV) on beech seedlings. PLO also improved the rate of infection on TNV in willows. In only one case, was CLRV transmitted conventionally to a white ash seedling. The infection of white ash was increased when frozen powders, of infected ash leaves were directly rubbed onto leaves. BMV could not be transmitted to beech seedlings by carborundum pressure-inoculation. Stem slashing-inoculation of BMV and CLRV was successful with CLRV in one beech out of 60 seedlings.     

Analysis of the occurrence and distribution of tobacco rattle virus in field soil and disease in a subsequent tulip crop

The occurrence and distribution of tobacco rattle virus (TRV) in field plots was determined by soil bait-testing and disease incidence in tulips subsequently grown on these plots was studied. The virus occurred in patches, calculated as 1.5 m × 3.6 m. The presence of virus was not correlated with numbers of potential vector trichodorid nematodes. Of three trichodorid nematode species present, only Paratrichodorus teres transmitted TRV which, as with virus isolates obtained in bait-tests and from infected tulips, reacted in serological tests with an antiserum prepared against a Dutch isolate of pea-early browning virus (PEBV). Virus prevalence in a subsequent tulip crop was 0.8% and in a sample of tulip plants, virus was recovered only from plants showing virus symptoms. Plots from which TRV was recovered in bait-tests yielded significantly more virus diseased tulips than plots which tested negative for virus. Growing bait-plants in field-plots, as compared with greenhouse tests using soil collected as a series of sub-samples, resulted in an underestimate of the occurrence of TRV.     

The effect of asparagus virus infection on asparagus tissue culture

The impact of asparagus virus I (AV-I), a potyvirus, and asparagus virus II (AV-II), an ilarvirus, on micropropagation of field-grown asparagus was studied. Apical shoot tips excised from singly or doubly-infected plants were slow to develop roots and had a 15 to 75% reduction in survival in culture, respectively, compared to those excised from virus-free plants. The four virus infection groups were ranked: virus-free >AV-II>AV-I>AV-I & II for capacity of explants to both root and survivein vitro. Micropropagated plants infected with AV-II exhibited slight reductions in fresh and dry weights, with greater reductions associated with infection with AV-I and double infection, compared to the virus-free controls. Eighty-one virus-infected apical shoot tips yielded 7 (8.6%) virus-free clones, as determined by rub inoculation on indicator plants.     

Arabis mosaic and Prunus necrotic ringspot viruses in hop (Humulus lupulus L.)

Purified virus preparations made from nettlehead-diseased hop plants, or from Chenopodium quinoa, to which the virus was transmitted by inoculation of sap, contained polyhedral virus particles of 30 mμ diameter which were identified serologically as arabis mosaic virus (AMV). There were serological differences between AMV isolates from hop and from strawberry, and also differences in host range and in symptoms caused in C. quinoa and C. amaranticolor. AMV was always associated with nettlehead disease. The nematode Xiphinema diversicaudatum occurred in small numbers in most hop gardens, but was numerous where nettlehead disease was spreading rapidly. Preparations from nettlehead-affected hops also contained a second virus, serologically related to Prunus necrotic ringspot virus (NRSV), in mild and virulent forms which infected the same range of test plants but showed some serological differences. Mild isolates did not protect C. quinoa plants against infection by virulent isolates. Hop seedlings inoculated with virulent isolates of NRSV developed symptoms indistinguishable from those of split leaf blotch disease. Latent infection with NRSV was prevalent in symptomless hop plants. Nettlehead disease is apparently associated with dual infection of AMV and virulent isolates of NRSV. An unnamed virus with rod-shaped particles 650 mμ long was common in hop and was transmitted by inoculation of sap to herbaceous plants. Cucumber mosaic virus was obtained from a single plant of Humulus scandens Merr.     

Aphid-transmitted viruses from lilies in Britain

Three aphid-transmitted viruses, tulip breaking, lily symptomless and cucumber mosaic, were obtained from lilies in Britain. Tulip breaking virus was detected by the leaf mottle produced in Lilium formosanum, cucumber mosaic virus by inoculation of sap to Nicotiana clevelandii and Chenopodium quinoa, and lily symptomless virus by electron microscopy of crude leaf extracts from symptomless L. formosanum. Liiy symptomless virus was transmitted by Myzus persicae, Macrosiphum euphorbiae, Aulacorthum solani and Aphis fabae. M. persicae, which in a small experiment appeared a more efficient vector than A. fabae, transmitted the virus in a non-persistent manner. This conflicts with the original report of transmission in a persistent manner by A. gossypii but no transmission by M. persicae. The possibility that there are two distinct viruses with similar pathological effects is discussed. Tulip breaking and lily symptomless viruses spread to bait plants of L. formosanum within a field planting of lilies in Scotland especially during July to September; lily symptomless virus was the more prevalent. No spread of cucumber mosaic virus was detected.     

Determination of Onion yellow dwarf virus concentration levels on onion bulb and leaf by double-antibody sandwich enzyme-linked immunosorbent assay (DAS-ELISA)

With the aim of understanding virus movement and fluctuations in the virus concentration in bulb and leaves of onion (Allium cepa L.) plants after infection, Onion yellow dwarf virus (OYDV) was analysed by double-antibody sandwich enzyme-linked immunosorbent assay (DAS-ELISA). OYDV concentrations were higher in onion leaves of plants grown from tested bulbs compared with bulbs, although the virus was successfully detected in bulb of onion.     

Tulip chlorotic blotch virus, a second potyvirus causing tulip flower break

Tulip chlorotic blotch virus (TCBV), an apparently undescribed potyvirus found in field grown tulips in Australia, causes symptoms in tulip leaves and flowers identical to those induced by tulip breaking virus (TBV). TCBV was transmitted mechanically to 14 of 34 species in four of 13 families. Nicotiana clevelandii is a suitable propagation host and Chenopodium amaranticolor a local-lesion assay host. TCBV was transmitted from tulip to tulip and TV. clevelandii by the aphid Myzus persicae. Unlike TBV it was not transmitted to Lilium formosanum either by M. persicae or by manual inoculation. Leaf extracts from TCBV-containing TV. clevelandii were infective after dilution to l0^-3 but not 10-⁴ and after heating for 10 min at 50°C but not 60°C; infectivity and particle recovery were adversely affected by freezing at -20°C. TCBV particles were purified (c. 1 mg/100g g N. clevelandii leaf) from tissue extracts in 0·3 M citrate buffer containing 10 mM EDTA and 0·2% (v/v) 2-mercaptoethanol at pH 7·4 by clarification with 8·5% (v/v) n-butanol followed by differential centrifugation and sucrose density gradient centrifugation. Purified particles measured c. 720 × 12 nm. Virus particle antigen was readily detected in leaf and tepal extracts of tulip by enzyme-linked immunosorbent assay. A distant serological relationship was found between particles of TCBV and those of bean yellow mosaic virus but no serological relationship was found to TBV or four other potyviruses.     

Transmission of the hop strain of arabis mosaic virus by Xiphinema diversicaudatum*

Hop plants became infected with the hop strain of arabis mosaic virus (AMV(H)) when grown in hopfield and woodland soil in which infected plants had been growing. Infection occurred in soil infested with the dagger nematode Xiphinema diversicaudatum, but neither in uninfested soil nor in soil previously heated to kill nematodes. X. diversicaudatum transferred direct from hop soils transmitted AMV(H) to young herbaceous plants and to hop seedlings; some of the hop seedlings developed nettlehead disease. A larger proportion of plants was infected using X. diversicaudatum obtained from a woodland soil and then given access to the roots of hop or herbaceous plants infected with AMV(H). AMV(H) was transmitted by adults and by larvae, in which the virus persisted for at least 36 and 29 wk, respectively. Difficulties were encountered in detecting AMV(H) in infected hop plants, due partly to the delay in virus movement from roots to shoots. Infection of hop shoots was seldom detected until the year after the roots were infested and sometimes nettlehead symptoms did not appear until the third year. Isolates of arabis mosiac virus from strawberry did not infect hop. The results are discussed in relation to the etiology and control of nettlehead and related diseases of hop.     

Pathogen-activated induced resistance of cucumber: response of arthropod herbivores to systemically protected leaves

Summary Restricted (non-systemic) inoculation of cucurbits, green bean, tobacco, and other plants with certain viruses, bacteria, or fungi has been shown to induce persistent, systemic resistance to a wide range of diseases caused by diverse pathogens. The non-specificity of this response has fueled speculation that it may also affect plant suitability for arthropod herbivores, and there is limited evidence, mainly from work with tobacco, which suggests that this may indeed occur. Young cucumber plants were immunized by restricted infection of a lower leaf with tobacco necrosis virus (TNV), and upper leaves were later challenged with anthracnose fungus, Colletotrichum lagenarium, to confirm induction of systemic resistance to a different pathogen. The response of arthropod herbivores was simultaneously measured on non-infected, systemically protected leaves of the same plants. As has been reported before, immunization with TNV gave a high degree of protection from C. lagenarium, reducing the number of lesions and the area of fungal necrosis by 65–93%. However, there was no systemic effect on population growth of twospotted spider mites, Tetranychus urticae Koch, on upper leaves, nor did restricted TNV infection of leaf tissue on one side of the mid-vein systemically affect mite performance on the opposite, virus-free side of the leaf. Similarly, there were no effects on growth rate, pupal weight, or survival when fall armyworm larvae were reared on systemically protected leaves from induced plants. In free-choice tests, greenhouse whiteflies oviposited indiscriminately on induced and control plants. Feeding preference of fall armyworms was variable, but striped cucumber beetles consistently fed more on induced than on control plants. There was no increase in levels of cucurbitacins, however, in systemically-protected foliage of induced plants. These findings indicate that pathogen-activated induced resistance of cucumber is unlikely to provide significant protection from herbivory. The mechanisms and specificity of induced resistance in cucurbits apparently differ in response to induction by pathogens or herbivores.     

Systemic Acquired Resistance Induced in Tobacco Plants by Localized Virus Infection Does Not Operate Against Challenging Viruses That Infect Systemically

Localized infections produced by tobacco necrosis virus (TNV) or tomato mosaic virus (ToMV) in White Burley tobacco induced a systemic acquired resistance in upper, uninoculated leaves. This resistance was effective against challenge infection by TNV or ToMV but not by potato virus Y, necrotic strain (PVYⁿ), tobacco mosaic virus (TMV) or tobacco rattle virus (TRV), viruses giving systemic infections. Systemic acquired resistance against TNV or ToMV was expressed as a reduction in lesion size but not in viral antigen content of the resulting necrotic local lesions. The acquisition of resistance was concurrent with an increased capacity of the resistant leaves to convert 1-aminocyclopropane-1-carboxylic acid into ethylene. Systemic acquired resistance was ineffective to contrast or minimize in whatever way the systemic challenge infection produced by PVY^N, TMV or TRV. Severity of symptoms and virus multiplication did not differ in resistant leaves from controls. This result does not allow any optimistic promise on possible application of the systemic acquired resistance against severe viral diseases of crops.