Abstracts

ARTIGOS/ARTICLES

EFFECTS OF SINGLE AND DOUBLE INFECTIONS WITH Potato virus X AND Tobacco mosaic virus ON DISEASE DEVELOPMENT, PLANT GROWTH, AND VIRUS ACCUMULATION IN TOMATO

OLUSEGUN S. BALOGUN, LEIXIN XU, TOHRU TERAOKA & DAIJIRO HOSOKAWA

Laboratory of plant pathology, Faculty of Agriculture, Tokyo University of Agriculture and Technology, Fuchu-shi, Tokyo 183-8509, Japan, e-mail: osbalo@cc.tuat.ac.jp

(Accepted for publication 21/09/2000)

Corresponding author: O. S. Balogun

ABSTRACT

The tomato cv. Fukuju n^o. 2 was used for studying the effect of single and double infections with Potato virus X (PVX) and Tobacco mosaic virus (TMV). Mixed infection resulted in a synergistic increase of disease severity, where more growth reduction was seen with simultaneous inoculations than with sequential inoculations at four-day intervals. At five and 12 days post-inoculation, the increased severity of the disease coincided with enhancement of virus accumulation in the rapidly expanding upper leaves. The PVX concentration in leaves n^o 5 to 7 of doubly infected plants was three to six fold that of singly infected ones, as determined by DAS-ELISA. Mixed infection with the L strain led to higher enhancement of PVX than with the TMV-L₁₁A strain. The concentration of TMV-L was lower in double infection and significantly higher than TMV-L₁₁A in both singly and doubly infected plants. Analyses of the PVX ORF2 by Western blot and Northern hybridization revealed the pattern of accumulation of the 25 kDa protein and the RNAs, respectively, following those of the virion and coat protein. The strain TMV-L₁₁A overcame the resistance gene in cv. GCR 237 (Tm-1). In the upper leaf n^o. 8, the concentration of PVX was three times higher in plants with mixed infection than with L₁₁A. The concentrations of the L and OM (TMV strains) in both singly and doubly infected plants were at very low levels, and the synergistic effect on PVX concentration and disease severity was not observed.

Additonal keywords: synergism, Western blot, Northern hybridization, DAS-ELISA, virus enhancement.

RESUMO

Efeito de infecções simples e dupla com Potato virus X e Tobacco mosaic virus sobre o desenvolvimento da doença, crescimento da planta e acumulação de vírus em tomate

A cultivar de tomate (Lycopersicon esculentum) Fukuju n^o 2 foi usada para estudar o efeito de infecçöes simples e duplas com o vírus X da batata (Potato virus X, PVX) e o vírus do mosaico do fumo (Tobacco mosaic virus, TMV). A infecção mista resultou em um aumento sinérgico da severidade da doença, mostrando maior redução no crescimento com inoculação simultânea do que com seqüencial. Entre cinco e 12 dias após a inoculação, o aumento da severidade da doença coincidiu com o incremento no acúmulo de vírus nas folhas jovens. A concentração de PVX nas folhas n^o 5 e 7 de plantas com infecção mista foi três a seis vezes mais que a observada com apenasPVX, conforme determinado por DAS-ELISA. A infecção mista com a estirpe L resultou em maior incremento de PVX do que com L₁₁A. A concentração do TMV-L foi mais baixa em infecção dupla e significativamente mais alta do que a de TMV-11A, tanto em infecção simples como em dupla. Análises da OR F2 de PVX por Western Blot e Northern hybridization revelaram o padrão de acúmulo da proteína 25 kDa e RNAs, respectivamente, seguindo aqueles dos viriões e capa proteica. A estirpe TMV-L₁₁A venceu a resistência genética na cv GCR 237 (Tm-1). Na folha superior n^o 8, a concentração de PVX foi três vezes maior nas plantas com infecção mista com T-MVL₁₁A. As concentrações das estirpes L e OM de TMV, tanto na infecção simples como dupla foram muito baixas e não se observou efeito sinérgico na concentração de PVX.

INTRODUCTION

Tomato (Lycopersicon esculentum Mill.), an annual plant of the family Solanaceae, is an important fruit crop in most parts of the world. Generally, a number of viruses singly infecting this host are known to have potential to inflict severe economic losses. These include several strains of the Tobacco mosaic virus (TMV) genusTobamovirus (Cassels & Herrick, 1977; Fraser et al., 1986). In nature, many diseases of great economic importance to growers result from a mixture of different agents impinging the host at a given time. A "streak disease" often occurs in tomato when mixed infected with TMV and Potato virus X (PVX)genus Potexvirus (Matthews, 1991). This is characterized by severe mosaic, leaf distortion, necrotic lesions, stunting, and even premature death of plants infected at a very young age.

Related and unrelated viruses can often replicate in the same cells and may interact synergistically or antagonistically (Otsuki & Takebe, 1976) while the concentration of one or both may significantly increase. In a mixed infection involving PVX and Potato virus Y family Potyviridae genus Potyvirus (PVY), PVX was reportedly enhanced while PVY remained unchanged (Vance, 1991). The titer of the Bean pod mottle virus (BPMV) family Comoviridae genus Comovirus in soybean [Glycine max (L.) Merril], as determined by enzymelinked immunosorbent assay (ELISA), varied with leaf position and correlated well with symptom severity in plants singly and doubly infected with Soybean mosaic virus (SMV) family Potyviridae genus Potyvirus (Calvert & Ghabrial, 1983).

Different mechanisms have been reported for enhancement of viruses under mixed infections. The increase of PVX by PVY or TMV in tobacco (Nicotiana tabacum L.) results from enhanced concentration and increased synthesis per cell and not from an increase in the number of cells infected (Goodman & Ross, 1974a). In the mixed infection involving Cucumber mosaic virus (CMV) family Bromoviridae genus Cucumovirus and Turnip mosaic virus (TuMV) family Potyviridae genus Potyvirus, the enhancement of CMV was largely attributed to an increase in the number of CMV-infected cells (Ishimoto et al., 1990). Barker (1987) attributed enhancement of Potato leafroll virus (PLRV) genus Luteovirus by PVY in tobacco to the enhanced transport of the virus. The increase of CMV concentration in cucumber (Cucumis sativus L.) plants co-infected with Zucchini yellow mosaic virus (ZYMV) family Potyviridae genus Potyvirus (Poolpol & Inouye, 1986). Vance (1991) reported alteration in the replication of PVX RNA leading to higher accumulation of anti-sense RNA of PVX in co-infections with PVY.

The objectives of this study were to evaluate the effect of TMV-susceptible and resistant cultivars, and severe and attenuated strains of TMV on the enhancement of PVX in mixed infected tomato, as well as elucidate mechanisms involved in disease development.

MATERIALS AND METHODS

Plants and viruses

Seedlings of Fukuju n^o 2, a common Japanese tomato cultivar, and GCR 237 (Tm-1), genetically resistant to TMV, were raised under greenhouse conditions with a maximum temperature of 30 ^oC and a minimum of 18 ^oC. Sandy loam soil, steam-sterilized at 121 ^oC for 30 min, and vermiculite including NPK elements, supplemented at planting and/or transplanting, served as the growth medium. The arrangement of the pots was completely randomized.

PVX strain O and TMV strains L, (tomato strain or Tomato mosaic virus), OM (wild strain), and L₁₁A (attenuated strain) multiplied in N. tabacum cv. Xanthi and purified by standard procedures were used. Plants at the 5-leaf stage were inoculated with each virus alone, or simultaneously with a mixture of equal quantities of PVX and TMV, by rubbing the lower two leaves, which were lightly dusted with carborundum with a suspension of 0.2 mg/ml of virus in phosphate buffer alone pH 7.0. Plants that were inoculated with the buffer only served as controls.

Preparation of antibodies

Antibodies against TMV (L, L₁₁A, and OM) and PVX were raised in rabbits essentially as described in Sambrook et al. (1989). The sera, collected seven days after the last booster inoculation, had a dilution end point titer value of 1:1,024 (tube precipitin test) and were used for purifying IgG by the saturated ammonium sulfate solution precipitation method. The purified IgG preparations, treated with acetone extracts-free powder prepared from healthy tomato leaves, were conjugated to enzyme grade alkaline phosphatase (E.C 3.1.3.1) from calf intestine (Wako Life science reagents, Japan) essentially according to the basic procedure outlined in short protocols in molecular biology (Ausubel et al., 1995).

Bacterial expression and purification of the PVX–ORF2 protein and antibody preparation

First strand cDNA, synthesized from PVX–RNA prepared from purified PVX particles, was extended from oligo (dT) by reverse transcriptase (RT), (Amersham). The complete ORF2–cDNA was synthesized by PCR using primers with 5': GATCAGATCTAAGATGGATATTCTCATC and 3': GATCAAGCTTAGTCTATGTCC CTGCGCG in 28 cycles of 94 ^oC for 20 s; 55 ^oC for 45 s; and 68 ^oC for 30 s. The synthesized cDNA was checked before being cloned into the pQE14 vector of QIA–expression system (QIAGEN), according to the standard protocol (Sambrook et al., 1989). The insertion of the ORF2 gene into the BglII–HindIII sites downstream of the 6x histidine–mouse dihydrofolate reductase of pQE14 generated a plasmid recombinant that was then transformed in Escherichia coli M15. Confirmation of expression of the fusion protein in several selected colonies was done by SDS-PAGE in small-scale experiments. The expression of the fusion protein was induced by addition of IPTG (2 mM) to a culture of the recombinant bacterium in LB medium containing ampicillin and kanamycin. After 4 h, the culture was harvested and lyzed for 1 h in Tris-phosphate (TP) buffer containing 8 M urea. The extract was centrifuged, and the supernatant passed through Ni-NTA resin column. The fusion protein, which was then eluted by gradient pH of TP buffer (containing 8 M urea), was confirmed by SDS-PAGE. Antibody specific to the protein was raised in rabbits following the same procedure outlined in Sambrook et al. (1989).

Sodium dodecyl sulfate-Polyacrylamide gel electrophoresis (SDS-PAGE) and Western blot analysis

Protein fractionation and Bestern blot analysis were carried out essentially by the standard method (Sambrook et al., 1989). Leaf samples from the same position were collected from infected and healthy plants and macerated, with precooled mortars and pestles, in homogenizing buffer (0.05 M Tris-HCl, pH 6.8 containing 0.1% PMSF or 0.1% 2-Mercaptoethanol) at a ratio of 1 g to 10 ml of buffer. Samples were analyzed on 12% or 15% gels and for immunoblotting analysis; proteins were electrotransferred to hybond-C extra nitrocellulose membrane (Amersham life science). Antiviral IgG and anti-25 kDa (PVX) antibody were used at 5 mg/ml of blocking buffer (5% skim milk in PBS containing 0.05% Tween 20 and 0.02% NaN₃), and goat anti-rabbit antibody-alkaline phosphatase conjugate (Biosource International, Camarillo Ca. USA) was used as secondary antibody at 1:1,000 dilution. Visualization of virus-specific protein bands was achieved in 15 ml of alkaline phosphatase buffer (100 mM Tris-HCl, pH 9.5; 100 mM NaCl; and 5 mM MgCl₂) containing 100 ml of 50 mg of nitro blue tetrazolium (NBT) per ml of 70% dimethylformamide and 50 ml of 5-bromo-4-chloro-3-indolyl phosphate (BCIP) per ml of dimethylformamide.

ELISA procedure

Conventional double antibody sandwich (DAS)-ELISA was carried out essentially according to the method of Clark & Adams (1977). Leaf samples were ground for 1 min in 0.02 M sodium-phosphate buffer, pH 7.2, with precooled mortars and pestles in the ratio of 1 g of tissue to 10 ml buffer. The homogenate was centrifuged for 10 min at 10,000 rpm and the supernatant, carefully removed, was diluted in two- fold steps in the homogenizing buffer from 1:100 to 1:12,800 for all treatments. Viral IgG-alkaline phosphatase conjugate was used at 2 mg/ml concentration, and color was developed with p-nitrophenyl phosphate, at 1 mg/ml concentration in 10% diethanolamine, pH 9.8. The concentration of each virus in the samples was estimated from a standard curve, established for each set of assay using purified virus preparations of each virus.

Isolation of RNA and Northern blot hybridization

Total RNA was isolated by the method of Logemann et al. (1987). Fresh leaf samples were frozen in liquid nitrogen and homogenized immediately to a fine powder and 2 vol. guanidine buffer [8 M guanidine hydrochloride, 20 mM Mes (4-morpholineethansulfonic acid), 20 mM EDTA, and 50 mM mercaptoethanol at pH 7.0] were added. The homogenate was extracted with phenol/chloroform/isoamyl (25:24:1), centrifuged and the aqueous layer treated with precooled 0.7 vol. ethanol and 0.2 vol. 1 M acetic acid to precipitate RNA. The pelleted RNA was washed twice with 3 M sodium acetate, pH 5.2, and finally with 70% ethanol.

An equal quantity of total RNA (20 mg) of each treatment sample was fractionated on 1.2% agarose gel and transferred by capillary elution to hybond nylon membrane in 20 X SSC. An RNA probe, complementary to 350 nts of the PVX coat protein gene, inserted into T7 plasmid vector and labeled with digoxigenin (DIG) (Boehringer Mannheim) according to the manufacturer's instructions, was hybridized to the total RNA. Prehybridization and hybridization as well as washing were carried out using the standard procedure (Sambrook et al., 1989). The immobilized PVX RNAs were immunodetected using anti-DIG alkaline phosphatase conjugate. Color was developed with NBT/BCIP, at twice the concentration for normal protein detection, in alkaline phosphatase buffer.

Disease development, plant growth and yield assessment

Data on symptom type and time of the first appearance, number of days to flowering after inoculation, plant height, number of leaves and stem girth were obtained. Leaf samples were collected at various periods postinoculation and kept frozen at –40 ^oC until assayed for virion, viral proteins or RNAs concentration. At harvest, some shoots were cut from the base while the roots were also removed from the soil, carefully rid of attached soil particles, and then weighed. Both shoots and roots were oven-dried to constant weight at 80 ^oC over 24 h. Fruits were harvested from the first round of flowering.

RESULTS

Symptoms, plant growth, and yield of singly and doubly infected plants

The manifestation of symptoms in cv. Fukuju n^o 2 tomato plants differed, both in time of appearance and in severity, depending on the virus strains, mode of inoculation, and season of growth (Table 1).

PVX infected plants of the cv. GCR 237 (Tm-1) manifested the usual symptoms, found in cv. Fukuju n^o 2. Of the TMV strains tested, however, only L₁₁A (attenuated strain) induced a delayed, moderate mosaic symptom. The L and OM (severe strains) did not induce any symptoms. Plants that were mixed infected with L₁₁A and PVX eventually developed a moderate form of the characteristic symptoms observed in doubly infected TMV-susceptible plants, but the effect on growth was minimal (data not shown).

The cv. Fukuju n^o 2 plants doubly infected with PVX and TMV had significantly more reduced growth and yield than the singly infected ones (Table 2). Plants inoculated with TMV-L₁₁A alone, or in combination with TMV-L, had generally better growth and yield than those infected with any of TMV-L and PVX. Healthy plants had significantly better height, leaves, stem girth, as well as shoot, root and fruit yield than the infected ones, with the exception of those with TMV-L₁₁A alone.

Comparative concentration of viruses in singly and doubly infected plants

PVX concentration: The inoculated primary leaves of cv. Fukuju n^o 2 plants had generally high PVX accumulation, as measured by ELISA, while no considerable differences were found between singly and doubly inoculated ones (Table 3). In singly infected plants, inoculated leaves contained higher concentration than the systemically infected ones, while in mixed infected plants, the systemically infected upper leaf n^o 5 or 7 had higher concentrations than the inoculated leaves.

The concentration in mixed infected upper leaves was also several-fold higher than that in comparable leaf positions of singly infected plants. Enhancement was consistently higher in plants with TMV-L + PVX, than in those with PVX and L₁₁A.

In the inoculated leaves of GCR 237 (Tm-1) plants, equally early substantial accumulation of PVX was found both in the singly inoculated and in doubly inoculated plants. PVX concentration in the systemically infected upper leaf 5, at 7 dpi (data not shown) and at 12 dpi (Table 4) remained at the same levels for both singly infected and doubly infected plants. In the uppermost leaf 8, at 18 dpi, PVX concentration was 3-fold higher than in plants with PVX + L₁₁A treatment, relative to singly inoculated plants, and those with TMV-L + PVX or PVX + TMV-OM treatments, all of which remained at the same levels.

TMV concentration: The mean concentrations of both TMV strains, in doubly infected cv. Fukuju n^o 2 plants were relatively lower than those in singly infected plants but TMV-L was found to be generally higher than that of the L₁₁A, single or mixed infection not withstanding (Table 3). The ratio of concentration in doubly infected plants to that in singly infected plants for the two strains was lower, leaf for leaf, for TMV-L than for TMV-L₁₁A, but was more pronounced in the systemically infected upper leaves.

In cv. GCR 237 (Tm-1), of all the TMV strains tested, only TMV-L₁₁A accumulated considerable levels in both singly and doubly inoculated plants. Although at undetectable level by ELISA, at 7 dpi, both in the inoculated and upper leaf 5, it reached some substantial level in leaf n^o 8 sampled and analyzed 18 days postinoculation (Table 4).

Virus-specific proteins accumulated in singly and doubly infected leaves

In the inoculated primary leaves of cv. Fukuju n^o 2 plants, both TMV and PVX coat proteins assayed 3, 5 or 7 dpi, by Western blot analysis, showed increased concentrations which remained respectively at about the same levels in both singly and doubly infected plants. TMV-L was detected in the upper leaf n^o 5 of plants under single inoculation 3 dpi. It increased to substantial levels at 5 dpi and then stabilized at 7 dpi. In contrast, however, its systemic movement and accumulation under mixed infection, to and in the upper leaves, fell short of the speed and the quantity observed in singly inoculated plants (Figure 1A, ^C , ^D ). PVX's CP concentration was higher and continued to increase in the doubly infected upper leaves compared to singly infected ones as at 12 dpi (Figure 2A).

The PVX ORF2-encoded 25 kDa triple gene block (TGB) protein was first faintly detected at 3 dpi in the inoculated leaves of both singly and doubly infected plants. The level at 5 dpi is shown in Figure 1B. The quantity in systemically infected leaves of doubly infected plants increased more rapidly with time than that in singly infected ones. Figure 2B shows the relative levels in leaves 5 and 7 at 12 dpi.

In cv. GCR 237 (Tm-1), relatively early high accumulation of PVX CP, was observed in both single and mixed infection. On the other hand, as at 7 dpi, the TMV strains were neither detected in the inoculated leaves (i.e. nos. 1 and 2) nor in leaf 5 by Western blot analysis. Samples at 12 dpi had substantial accumulation of L₁₁A in leaf n^o 5 in both singly and doubly infected plants (Figure 3). The OM strain's CP was detected only by 18 dpi, albeit in very minute quantity, but that of L was not. Significantly higher concentrations of PVX CP were observed in plants with PVX plus L₁₁A.

PVX RNA accumulated in singly and mixed infected plants

A time course analysis of the acute stage leaf n^o 5 from cv. Fukuju n^o 2 plants, from day five through 12, by Northern blot hybridization of total RNA, revealed the gradual accumulation of both the genomic and subgenomic RNAs in all infected plants. The doubly infected leaf, however, had considerably bolder hybridization signal in contrast to singly infected ones, especially at 5 and 12 dpi. The differences became less apparent, with age of infections, as observed in the chronic stage upper leaf n^o 12 sampled at 28 dpi (data not shown).

DISCUSSION

The enhancement of PVX viral components during disease development, as influenced by differences in TMV strains and tomato host cultivar, exert substantial influence on the consequent tomato responses. The observed differences, both in the extent of individual replication and PVX-enhancing ability between the two strains of TMV may have stemmed from their basic genomic differences. Indeed, comparison of the complete nucleotide sequence of L₁₁A with that of the ancestral wild strain (L) Nishiguchi et al. (1985) showed ten nucleotide substitutions in L₁₁A, all located in the 130 K and 180 K protein genes. Amino acid changes were, however, associated with only three of the nucleotide substitutions. The 130 K and 180 K proteins are known to take part in virus RNA replication (Ishikawa et al., 1986).

In relation to earlier reports on mixed infection, our results are in line with those of some earlier workers (Calvert & Ghabrial, 1983; Vance, 1991) who also reported lack of significant enhancement of any of the interacting viruses in the inoculated leaves. Although they reported no changes in the concentration of the enhancing virus, in the acute stage upper leaves of tomato that would support enhancement of PVX, we observed that the mean concentration of TMV-L was about 25 % lower than the average in comparable leaves of singly infected plants (Table 4). The effects of the mild strain, however, remained at about the same level in both cases, which further supports our idea that TMV strains do influence the enhancement of PVX, and hence the general mixed infection process. Poolpol & Inouye (1986) reported a reduction in the concentration of ZYMV in doubly infected plants while that of CMV increased in cucumber plants.

In cv. GCR 237 with the Tm-1 gene that confers homozygous resistance to some TMV strains, the L and OM strains accumulated to very low levels in systemically infected upper leaves in both singly and doubly inoculated plants.Consequently, despite concentration of PVX remaining high, there was no significant enhancement in the doubly over singly infected plants. The absence of the characteristic symptoms of mixed infection was also notable. The L₁₁A strain that substantially accumulated early enough to overcome the resistance led to enhanced concentration of PVX in mixed infected plants. It is apparent from these results that the mere presence of TMV strains in the mixed infection is not a sufficient requirement for the enhancement of PVX concentration. The enhancing TMV strain must not only be able to replicate in the host cultivar, it also must be capable of doing so to a certain substantial level, at a time that coincides with active PVX replication. Goodman & Ross (1974b) have also observed that enhancement of the synthesis of PVX by PVY in doubly infected tobacco depends on the timing of invasion by the viruses.

Movement enhancing by TMV is one possible mechanism employed in the overall concentration-enhancement of PVX in tomato. Significant differences were observed between inoculated and systemically infected leaves within the respective treatments. Western blot analysis also showed that the systemic movements of TMV-L as well as its concentration are slowed significantly under simultaneous mixed infection with PVX (Figure 1A, ^C , ^D ). These results supports this possibility.

The relatively enhanced level of the 25 kDa protein in the systemically infected leaves may also have some implication for overall PVX concentration enhancement in mixed infected plants. The ability of PVX to increase the plasmodesmal size exclusion limit (SEL) of infected tobacco cell has been attributed to the 25 kDa TGB protein (Angell et al., 1996), although other viral proteins may also be involved. The enhanced level may also have led to the reductions observed in TMV concentration, through a possible slowing-down-strategy, in doubly infected plants. Ares et al. (1998) reported a substantial resistance to TMV in transgenic tobacco plant expressing the ORF2 protein (P24) of PVX.

The considerably high level of PVX genomic RNA, in the TMV-susceptible tomato cultivar (Figure 4), especially as observed during the acute stage of disease, could be responsible for sustained high synthesis of virion and, hence, the higher accumulation of virion. A change in the regulation of PVX RNA replication in doubly infected cells was also credited with the synergistic increase in PVX accumulation in a mixed infection with PVY (Vance, 1991), and this was invariably associated with increased pathogenicity in tobacco plants.

This study demonstrated that a mixed infection of tomato with TMV and PVX, which normally results in more severe disease symptoms involves alterations in the accumulation of PVX components.

This is influenced to a considerable extent by virus strains and the cultivars of tomato involved. The best long-term means of protection, as observed by Crute & Pink (1996), has proven to be cultivar-specific resistance controlled by a resistance gene that is specific to a particular virus, therefore, is the best hope for curtailing the disease studied.

ACKNOWLEDGEMENT

This work was supported by a grant-in-aid from the Japanese Ministry of Education, Science and Culture (Monbusho), for which we are grateful.

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