Relation of in vivo morphology to isolation of plant spiroplasmas

Two procedures were developed to isolate plant spiroplasmas directly onto DG-2 agar plates or in DG-2 broth without subcultures or dilutions. The frequency of successful spiroplasma isolations was increased by centrifuging samples, after passing through a 0.45-μm filter, at 25,000 × g for 1 h. Spiroplasmas were obtained from peach, cherry, Madagascar periwinkle, and celery with typical symptoms of the Green Valley strain of X disease (GVX), from peach with typical symptoms of the peach yellow leaf roll strain of X disease (PYLR), from Madagascar periwinkle with typical symptoms of aster yellows (AY), from celery with atypical symptoms of GVX (mild GVX), from plantago with atypical symptoms of aster yellows (mild AY), and from stubborn-diseased citrus. Isolations were consistent (>90%) from plants with mild GVX, mild AY, and citrus stubborn, while isolations were inconsistent (0–9%) from plants with typical symptoms of GVX, PYLR, and AY. The role of the isolated spiroplasmas in plant disease was not determined in this study. All spiroplasma isolates were serologically indistinguishable fromSpiroplasma citri. Spiroplasmas were seen in electron micrographs of 8 out of 9 examined plants from which spiroplasmas were isolated. However, electron micrographs of all 13 examined plants from which no spiroplasmas were isolated contained mycoplasma-like organisms (MLOs) but no, spiroplasmas. These results indicate that there is a correlation between helical MLOs in vivo and successful isolation of spiroplasmas, and that plants may be infected with bothS. citri and nonhelical mycoplasmas.     

Sugar import and phytopathogenicity of Spiroplasma citri: glucose and fructose play distinct roles

We have shown previously that the glucose PTS (phosphotransferase system) permease enzyme II of Spiroplasma citri is split into two distinct polypeptides, which are encoded by two separate genes, crr and ptsG. A S. citri mutant was obtained by disruption of ptsG through homologous recombination and was proved unable to import glucose. The ptsG mutant (GII3-glc1) was transmitted to periwinkle (Catharanthus roseus) plants through injection to the leaf-hopper vector. In contrast to the previously characterized fructose operon mutant GMT 553, which was found virtually nonpathogenic, the ptsG mutant GII3-glc1 induced severe symptoms similar to those induced by the wild-type strain GII-3. These results, indicating that fructose and glucose utilization were not equally involved in pathogenicity, were consistent with biochemical data showing that, in the presence of both sugars, S. citri used fructose preferentially. Proton nuclear magnetic resonance analyses of carbohydrates in plant extracts revealed the accumulation of soluble sugars, particularly glucose, in plants infected by S. citri GII-3 or GII3-glc1 but not in those infected by GMT 553. From these data, a hypothetical model was proposed to establish the relationship between fructose utilization by the spiroplasmas present in the phloem sieve tubes and glucose accumulation in the leaves of S. citri infected plants.     

DNA probes in detection of spiroplasmas and mycoplasma-like organisms in plants and insects

Abstract DNA probes were applied to detect spiroplasmas and uncultivable mycoplasma-like organisms (MLOs) in infected plants and insects. The probes consisted of pMC5, a plasmid carrying the RNA genes of Mycoplasma capricolum and pRA1, a plasmid recovered from Spiroplasma citri . Southern blot hybridization of pMC5 with digested DNAs of periwinkle plants infected with S. citri , or with various MLOs, yielded 2 heavy and several weaker bands. The heavy hybridization bands were shown to represent rRNA genes of the plant chloroplasts, indicating significant nucleotide sequence homology between the mycoplasmal rRNA genes and those of plant chloroplasts. Some of the weaker hybridization bands, not revealed in DNA of healthy plants, appeared to represent rRNA gene sequences of the infectious agent. Use of the spiroplasma plasmid as a probe enabled the detection of S. citri in infected plant material and in hemolymph of infected leafhoppers at a high sensitivity level.     

Chemically Defined Medium for Cultivation of Several Epiphytic and Phytopathogenic Spiroplasmas

A chemically defined medium, LD82, was formulated for in vitro cultivation of spiroplasmas. Medium LD82 supported good growth for four epiphytic and insect-pathogenic spiroplasmas, Spiroplasma floricola 23-6^T, Spiroplasma sp. strain SR3, Spiroplasma sp. strain brevi, and Spiroplasma sp. strain AS576, and of the phytopathogenic spiroplasmas Spiroplasma citri Maroc R8A2^T and PC1. Titers of all six strains grown in defined medium LD82 reached 2.0 × 10⁹ to 6.0 × 10⁹ CFU/ml of culture. All spiroplasma strains tested formed colonies readily on agar medium LD82. None of the spiroplasmas formed typical fried-egg colonies. All formed diffuse colonies, but the forms of colonies differed somewhat among the spiroplasma strains. In preliminary studies of nutritional requirements, phospholipids slightly enhanced the growth of the epiphytic and insect-pathogenic strains in medium LD82 and were found essential for good growth of S. citri.     

Fructose utilization and phytopathogenicity of Spiroplasma citri

Spiroplasma citri is a plant-pathogenic mollicute. Recently, the so-called nonphytopathogenic S. citri mutant GMT 553 was obtained by insertion of transposon Tn4001 into the first gene of the fructose operon. Additional fructose operon mutants were produced either by gene disruption or selection of spontaneous xylitol-resistant strains. The behavior of these spiroplasma mutants in the periwinkle plants has been studied. Plants infected via leafhoppers with the wild-type strain GII-3 began to show symptoms during the first week following the insect-transmission period, and the symptoms rapidly became severe. With the fructose operon mutants, symptoms appeared only during the fourth week and remained mild, except when reversion to a fructose+ phenotype occurred. In this case, the fructose+ revertants quickly overtook the fructose- mutants and the symptoms soon became severe. When mutant GMT 553 was complemented with the fructose operon genes that restore fructose utilization, severe pathogenicity, similar to that of the wild-type strain, was also restored. Finally, plants infected with the wild-type strain and grown at 23 degrees C instead of 30 degrees C showed late symptoms, but these rapidly became severe. These results are discussed in light of the role of fructose in plants. Fructose utilization by the spiroplasmas could impair sucrose loading into the sieve tubes by the companion cells and result in accumulation of carbohydrates in source leaves and depletion of carbon sources in sink tissues.     

Virus-mediated change in clumping properties ofDrosophila SR spiroplasmas

Transovarially transmitted SR spiroplasmas inDrosophila cause an abnormal sex ratio (SR condition: male-specific killing) in the host fly progenies. A reaction known as clumping takes place between different SR spiroplasma strains in which spiroplasmas instantly form aggregates upon mixing of the two strains. Each strain of SR spiroplasma carries an associated virus that is lytic to certain other strains. When the virus, HIV, from the recently discovered non-male-killingDrosophila hydei spiroplasma (HIS) is injected into host flies carrying the SR spiroplasma ofD. nebulosa (NSR), the latter spiroplasmas either undergo complete lysis and disappear, or survive with decreased numbers and with an abnormal morphology, and are transmissible from generation to generation in host flies. The surviving spiroplasmas possess two viruses, the endogenous virus of thenebulosa spiroplasma, spv-1, and the newly introduced superinfecting virus, HIV. This combination leads to a change in the surface properties of the superinfected spiroplasmas that is manifested in their ability to form clumps with normalnebulosa spiroplasmas, but does not interfere with male killing. This change in spiroplasma phenotype is discussed in terms of host-phenotype modification by infecting viruses.     

Viruses associated with chlorotic rosette and green rosette diseases of groundnut in Nigeria*

Groundnut (Arachis hypogaea) plants from Nigeria with chlorotic rosette disease contained a manually transmissible virus, considered to be a strain of groundnut rosette virus (GRV(C)). GRV(C) infected nine out of 32 species in three out of nine families. It caused local lesions without systemic infection in Chenopodium amaranticolor, C. murale and C. quinoa, and systemic symptoms in Glycine max, Nicotiana benthamiana, N. clevelandii and Phaseolus vulgaris as well as in groundnut. Some ‘rosette-resistant’ groundnut lines were also infected. GRV(C) was transmitted by Aphis craccivora, but only from groundnut plants that were also infected with an aphid-transmissible second virus, which was not manually transmissible and was considered to be groundnut rosette assistor virus (GRAV). Plants infected with GRAV contained isometric particles c. 25 nm in diameter which were detectable by immunosorbent electron microscopy on grids coated with antisera to several luteoviruses, especially with antisera to bean leaf roll, potato leafroll and beet western yellows viruses. No virus-like particles were observed in extracts from plants infected with GRV(C) alone. A single groundnut plant obtained from Nigeria with symptoms of green rosette contained luteovirus particles, presumed to be of GRAV, and yielded a manually transmissible virus that induced symptoms similar to those of GRV(C) in C. amaranticolor but gave only mild or symptomless infection of N. benthamiana and N. clevelandii. It was considered to be a strain of GRV and designated GRV(G).     

Purification and Identification of a South African Isolate of Watermelon Mosaic Virus – Morocco

Cucurbit crops in South Africa are seriously affected by a flexuous rod-shaped virus 706 to 770 nm long which causes the plant to be stunted, the leaves to display symptoms of chlorotic mosaic, dark green blisters and malformation, and fruit to be malformed. The virus was purified from infected Cucurbita pepo by extraction in 0.5 M borate buffer, pH 8, containing ethylenediaminotetra-acetic acid and mercapto-ethanol, clarification with chloroform, addition of Triton X-100, sedimentation by ultracentrifugation for which a sucrose cushion was used and centrifugation in 10 to 40 % sucrose gradients. The virus was mechanically transmitted to a limited host range with Chenopodium album, C. amaranticolor, C. quinoa and Gomphrena globosa being the only hosts infected outside the Cucurbitaceae. Luffa cylindrica, Cucumis metuliferus, Coccinia sessilifolia and Citrullus ecirrhosus all members of the Cucurbitaceae, were not infected by the virus. The virus was non-persistently transmitted by Myzus persicae, produced pinwheel and bundle inclusions in the plant cell cytoplasm and has a single coat protein with a molecular weight of 36,000 daltons and a degraded lighter component of 26,000 daltons. Serological comparisons with antiserum to watermelon mosaic virus 2, Papaya ringspot virus strain W and watermelon mosaic virus Morocco (WMV-Mor.) identified the virus as an isolate of WMV-Mor. It was found that WMV-Mor. is the dominant virus in all the main cucurbit producing areas of South Africa which were surveyed.     

Infectivity of beetle spiroplasmas for new host species

Five beetle spiroplasmas, the Colorado potato beetlespiroplasma (CPBS, strain LD-1), the Cantharis carolinusspiroplasma (CCBS, strain CC-1), the Ellychnia corrusca fireflyspiroplasma (FS, strain EC-1), the Diabrotica undecimpunctatacorn rootworm spiroplasma (CRS, strain DU-1), and the Spiroplasmafloricola fall flower spiroplasma (FFS), all associated withbeetles, were fed to beetles (Maladera matrida and Carpophilushumeralis) and mosquitoes (Aedes aegypti and Culex pipiens). CPBSand CCBS were also injected into M. matrida. Attempts to recoverspiroplasmas from regurgitates and hemolymph were conducted 1–10days after their introduction. After day 1, orally administeredspiroplasmas could not be recovered from M. matrida beetles;however, at 2–5 days, four out of five spiroplasmas wererecovered from adult C. humeralis. Injected spiroplasmas survivedin the hemolymph of M. matrida beetles for a relatively longperiod (at least 22 days). All five spiroplasmas were recoveredfrom mosquitoes 1 day post feeding, but only two (CCBS and CRS)survived for five or more days. The results show short andvariable persistence in orally challenged non-host insects, withgeneral failure to pass the gut barrier. Such evidence should beconsidered when attempting to use these microbes in biocontrolprograms.     

Further Observations on the Effects of Cymbidium Mosaic Virus and Odontoglossum Ringspot Virus on the Growth of Cymbidium Orchids

Two cultivars of Cymbidium orchid were mechanically inoculated with Odontoglossum ringspot virus (ORSV) and Cymbidium mosaic virus (CyMV), individually and in combination, one year after transfer from in vitro culture to the glasshouse. Plant growth and disease symptoms were monitored over the following 4 years. Plants infected with CyMV showed severe mosaic symptoms with necrotic streaks and the virus was easily detectable by ELISA throughout the experiment. Plants infected with ORSV alone showed no obvious symptoms, and by the end of the experiment the virus could not be detected in the new growth using ELISA. Both viruses reduced plant growth, the effect of CyMV being more severe than that of ORSV.     

Transmission of Spiroplasma citri by the aster leafhopper Macrosteles fascifrons (Homoptera: Cicadellidae)

The aster leafhopper (Macrosteles fascifrons), injected with an isolate of Spiroplasma citri obtained from brittle root-diseased horseradish (Armoracia rusticana), transmitted the spiroplasma to horseradish and China aster (Callistephus chinensis.) After feeding on plants infected with S. citri, M. fascifrons transmitted the spiroplasma from aster to aster and horseradish, from yellow rocket (Barbarea vulgaris) to aster, and from turnip (Brassica rapa) to turnip. Symptoms in infected horseradish were chlorosis and stunting of newly formed leaves, discoloration of root phloem, and reduced plant growth typical of brittle root disease. Chlorosis, stunting, and asymmetry of young leaves occurred in affected aster and turnip. Flowers of infected aster were small and pale in colour and occasionally showed other symptoms including asymmetry, petal distortion, or light green petals. Spiroplasmas were isolated from all plants showing symptoms. Transmission rates by M. fascifrons which acquired S. citri by feeding on infected plants were very low, but injected leafhoppers transmitted more frequently. This is the first report of the transmission of S. citri from diseased to healthy plants by M. fascifrons.     

Direct isolation in cell-free medium of a spiroplasma fromHaemaphysalis leporispalustris (Acari: Ixodidae) in Maryland

A spiroplasma isolate, was obtained from rabbit ticks (Haemaphysalis leporispalustris) taken from cottontail rabbits in Maryland by inoculation of tick suspensions into SP-4 medium. The isolate was indistinguishable from an experimental vertebrate pathogen (suckling mouse cataract agent spiroplasma) when tested with other plant and tick spiroplasmas in growth inhibition, deformation, and metabolism inhibition tests. The isolated organism had a pathogenic profile for suckling rats and embryonated chicken eggs that differed significantly from that of other suckling mouse cataract agent strains. This is the first report of a direct spiroplasma isolation from ticks in cell-free medium, and confirms the specific association of spiroplasmas of the suckling mouse cataract agent serogroup with rabbit ticks.     

Particle purification and properties of cassava Ivorian bacilliform virus

A virus found in cassava from the north-west of the Ivory Coast was transmitted by inoculation with sap extracts to herbaceous species in six plant families. Chenopodium quinoa was used as a propagation host and C. murale was used for local lesion assays. The virus particles are bacilliform, c. 18 nm in diameter, with predominant lengths of 42,49 and 76 nm and a structure apparently similar to that found in alfalfa mosaic virus. Purified preparations of virus particles had A₂₆₀/A₂₈₀ of 1.7 ±0.05, contained one protein of M_rc. 22 000, and yielded three species of RNA with M_r (× 10^-6) of c. 0.7, 0.8 and 1.2. Although the virus particles were poorly immunogenic, an antiserum was produced and the virus was detected by enzyme-linked immunosorbent assay (DAS-ELISA) in leaf extracts at concentrations down to c. 6 ng/ml. Four other field isolates were also detected, including a strain which caused only mild systemic symptoms in C. quinoa instead of necrosis. The naturally infected cassava source plants were also infected with African cassava mosaic virus (ACMV) but when the new virus was cultured in Nicotiana benthamiana, either separately or together with ACMV, its concentration was the same. The new virus did not react with antisera to several plant viruses with small bacilliform or quasi-bacilliform particles, and alfalfa mosaic virus reacted only weakly and inconsistently with antiserum to the cassava virus. The new virus, for which the name cassava Ivorian bacilliform virus is proposed, is tentatively classified as the second member of the alfalfa mosaic virus group.     

Tests for transmission of four potato viruses through potato true seed

The Andean potato calico strain of tobacco ringspot virus (TRSV-Ca) was detected in 2–9% of potato seedlings grown from true seed from plants of cv. Cara and clone G5998(6) infected with TRSV-Ca. Similarly, a potato isolate of the oca strain of arracacha virus B (AVB-O) was detected in 4–12% of progeny seedlings of cv. Cara and clone D42/8 infected with AVB-O. Potato virus T (PVT) passed through 33–59% of seed from PVT-infected cv. Cara, but only 0–2% infection was detected in seedlings from seed of PVT-infected clone D42/8. By contrast, no infection was detected in seedlings grown from seed from plants of G5998(6), D42/8 or cv. Cara infected with Andean potato latent virus strains Hu (APLV-Hu) or Caj (APLV-Caj), although both strains passed through seed of Nicotiana clevelandii. AVB-O, PVT and TRSV-Ca were detected in all tests of pollen from flowers of infected potato plants, but APLV-Hu and APLV-Caj were detected less frequently. AVB-O and PVT were transmitted through 2% and 8% respectively, of seed from healthy potato plants pollinated with pollen from infected plants. However, no transmission through seed was detected when pollen from TRSV-Ca infected plants was used. None of the four viruses were transmitted to healthy potato plants pollinated with pollen from infected plants. APLV-Hu caused exceptionally severe symptoms in the cv. Cara plants used for seed production, but the Bolivian strain of PVT induced only mild symptoms rather than the severe systemic necrosis previously reported for the type of strain of PVT in this cultivar. No symptoms developed in potato seedlings infected with TRSV-Ca, AVB-O or PVT through the seed.     

Detection of <Emphasis Type="Italic">Brevipalpus</Emphasis>-transmitted viruses in their mite vectors by RT–PCR

The diagnosis of plant diseases caused by Brevipalpus-transmitted viruses (BrTVs) has been done through the analyses of symptoms, transmission electron microscopy, and RT–PCR of infected plant tissues. Here, we report the detection of Citrus leprosis virus C, Orchid fleck virus, Clerodendrum chlorotic spot virus and Solanum violaefolium ringspot virus in their viruliferous vectors Brevipalpus spp. using specific primer pairs for each of the viruses. The efficiency of virus transmission by Brevipalpus mites is low, so the detection of these pathogens in their vectors could constitute an important tool for studies involving virus-vector relationships, transmission, and monitoring the pathogen prior to the appearance of symptoms in the field.     

Spiroplasmas are the causal agents of citrus little-leaf disease

A spiroplasma isolated from citrus with little-leaf disease was grown in a cell-free medium and injected into leafhoppers (Euscelis plebejus) Injected leafhoppers, but not those fed on infected plants, transmitted the spiroplasma to white clover (Trifolium repens cv. S100) and sweet orange (Citrus sinensis cv. Valencia). Infected clover plants were severely stunted; infected sweet orange plants showed typical symptoms of citrus little-leaf disease. The spiroplasma was detected in clover and sweet orange plants by electron microscopy; the helical morphology of the organisms was most easily recognizable in sections 150–200 nm thick. The organism was re-isolated in cell-free media both from infected plants and from injected E. plebejus. The original isolate and those re-isolated from experimentally infected clover and sweet orange appeared by morphological, cultural, biochemical and serological criteria to be identical to each other and to the R8-A2 (type) and C-189 strains of Spiroplasma citri. Serological tests and electrophoretic analysis of protein preparations indicated no relationship to Acholeplasma laidlawii, although this organism survived for at least 10 wk after injection into E. plebejus. Our results show that the causal agent of little-leaf disease is related to S. citri.     

A strain of radish mosaic virus occurring in turnip in Yugoslavia

Fields of turnip (Brassica rapa L. var. rapa) in Yugoslavia often contained plants infected with radish mosaic virus (RaMV). Yugoslav isolates resemble the type strain in host range, symptoms, physical properties, particle morphology and flea-beetle transmission and are serologically closely related to the type strain, but did not infect radish and are designated as the European strain. Light microscopy of infected turnip and some other cruciferous species revealed the characteristic inclusion bodies in the cytoplasm.     

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.     

Infection of potato plants with potato leafroll virus changes attraction and feeding behaviour of Myzus persicae

Potato leafroll virus (PLRV; genus Polerovirus, family Luteoviridae) is a persistently transmitted circulative virus that depends on aphids for spreading. The primary vector of PLRV is the aphid Myzus persicae (Sulzer) (Homoptera: Aphididae). Solanum tuberosum L. potato cv. Kardal (Solanaceae) has a certain degree of resistance to M. persicae: young leaves seem to be resistant, whereas senescent leaves are susceptible. In this study, we investigated whether PLRV‐infection of potato plants affected aphid behaviour. We found that M. persicae's ability to differentiate headspace volatiles emitted from PLRV‐infected and non‐infected potato plants depends on the age of the leaf. In young apical leaves, no difference in aphid attraction was found between PLRV‐infected and non‐infected leaves. In fact, hardly any aphids were attracted. On the contrary, in mature leaves, headspace volatiles from virus infected leaves attracted the aphids. We also studied the effect of PLRV‐infection on probing and feeding behaviour (plant penetration) of M. persicae using the electrical penetration graph technique (DC system). Several differences were observed between plant penetration in PLRV‐infected and non‐infected plants, but only after infected plants showed visual symptoms of PLRV infection. The effects of PLRV‐infection in plants on the behaviour of M. persicae, the vector of the virus, and the implications of these effects on the transmission of the virus are thoroughly discussed.