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.     

Identity of cactus and lettuce spiroplasmas withSpiroplasma citri as determined by DNA-DNA hybridization

The isolation of spiroplasma strains from the cactusOpuntia tuna monstrosa and from aster yellows-diseased lettuce is described. DNA from these strains (ATCC 29594 and ATCC 29747) is compared with DNA fromSpiroplasma citri, and from the corn stunt and suckling mouse cataract spiroplasmas. The cactus and the lettuce isolates are found to be identical withS. citri by this method.     

Translocation and multiplication ofSpiroplasma citri in turnip (Brassica rapa)

Following inoculation of designated leaves of turnip plants withSpiroplasma citri byCirculifer tenellus, spiroplasmas were cultured first from roots (four days) and then from youngest leaves (eight days), but almost never from oldest leaves. In experiments using enzyme-linked immunosorbent assay to monitor changes in titer in turnip leaves during the course of plant infection,S. citri was detected seven days after inoculation and reached peak titers of 10¹⁰–10¹¹ colony-forming units/g 12–20 days after inoculation, declining thereafter. Spiroplasmas were detected 5–9 days before symptoms appeared.     

Characterization of Spiroplasmas by one- and two-dimensional protein analysis on polyacrylamide slab gels

Differences betweenSpiroplasma citri isolates were detected by one-dimensional electrophoresis of proteins on gradient polyacrylamide slab gels. Two-dimensional protein maps (electrofocusing followed by electrophoresis) showed a highly characteristic pattern for allS. citri isolates examined. Coanalysis of mixed protein samples from pairs ofS. citri strains revealed more than 150 comigrating proteins common to allS. citri isolates, but also a number of noncomigrating proteins. Some noncomigrating proteins were present in one isolate but not in another, while other proteins whose migrational properties were only slightly different from one isolate to the other (homologous proteins), were present in more than one isolate.S. citri isolates had many common and only a few homologous proteins. Comparisons ofS. citri with the corn stunt spiroplasma revealed few common proteins and a large number of homologous proteins. When comparingS. citri and the suckling mouse cataract spiroplasma, few common and homologous proteins were apparent. However, several of these common proteins were also shared by the corn stunt spiroplasma, suggesting that they may well represent genus-specific proteins. The data also offer additional evidence that the suckling mouse cataract spiroplasma differs significantly fromS. citri and corn stunt spiroplasmas and probably deserves a separate species designation.     

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.     

Disruption of a Gene Predicted To Encode a Solute Binding Protein of an ABC Transporter Reduces Transmission of Spiroplasma citri by the Leafhopper Circulifer haematoceps

Spiroplasma citri is transmitted from plant to plant by phloem-feeding leafhoppers. In an attempt to identify mechanisms involved in transmission, mutants of S. citri affected in their transmission must be available. For this purpose, transposon (Tn4001) mutagenesis was used to produce mutants which have been screened for their ability to be transmitted by the leafhopper vector Circulifer haematoceps to periwinkle plants. With one mutant (G76) which multiplied in leafhoppers as efficiently as S. citri wild-type (wt) strain GII-3, the plants showed symptoms 4 to 5 weeks later than those infected with wt GII-3. Thirty to fifty percent of plants exposed to leafhoppers injected with G76 remained symptomless, whereas for wt GII-3, all plants exposed to the transmission showed severe symptoms. This suggests that the mutant G76 was injected into plants by the leafhoppers less efficiently than wt GII-3. To check this possibility, the number of spiroplasma cells injected by a leafhopper through a Parafilm membrane into SP4 medium was determined. Thirty times less mutant G76 than wt GII-3 was transmitted through the membrane. These results suggest that mutant G76 was affected either in its capacity to penetrate the salivary glands and/or to multiply within them. In mutant G76, transposon Tn4001 was shown to be inserted into a gene encoding a putative lipoprotein (Sc76) In the ABCdb database Sc76 protein was noted as a solute binding protein of an ABC transporter of the family S1_b. Functional complementation of the G76 mutant with the Sc76 gene restored the wild phenotype, showing that Sc76 protein is involved in S. citri transmission by the leafhopper vector C. haematoceps.     

Free and integrated plasmid DNA in spiroplasmas

Spiroplasma citri was found to carry an 8.0 kb plasmid that differed from previously describedS. citri plasmids in its restriction map. It was also clonable in pBR322. The plasmid, named pRA1, was found in large quantities as free plasmid inS. citri (R8A2, Maroc) subclones of low passage level. In subclones of higher passage levels, free plasmid was replaced by plasmid sequences integrated into the spiroplasma chromosome. Significant quantities of integrated plasmid sequences were also observed in the corn stunt spiroplasma,S. kunkelii, while small quantities of free and/or integrated plasmid DNA could be detected in some spiroplasmas serologically and genotypically remote fromS. citri. Integrated plasmid sequences were cloned into theEscherichia coli plasmid pUC13. Hybridization tests and restriction maps of these clones indicated that the integrated plasmid sequences consisted of fragments, rather than entire plasmid DNA, inserted into specific sites in the spiroplasma chromosome. Although the biological role of the pRA1 plasmid remains unclear, theS. citri subclones containing large quantities of free plasmid exhibited slower growth rates and a tendency to lyse.     

Multiplication of the agent of X-disease in a non-vector leafhopper Macrostelesfascifrons

The relative titre of the causal agent of X-disease of stone fruits in the non-vector leafhopper Macrosteles fascifrons was tested by injecting dilutions of M. fascifrons extracts into non-infective Colladonus montanus leafhopper vectors. The recipient C. montanus were fed on celery test plants which were then observed for X-disease symptoms. M. fascifrons were assayed at various intervals for up to 37 days after they were fed on X-diseased celery or injected with infectious extracts of the X-agent. Infectivity was detected in M. fascifrons only after 25 or 37 days in separate trials. Whole body extracts but not extracts from detached heads of M. fascifrons that had fed on X-diseased celery were infectious, whereas extracts prepared from the heads of M. fascifrons previously injected with X-agent extracts were infectious. This infectivity was retained for up to four serial passages in M. fascifrons. Electron microscopy of M. fascifrons that had been injected with extracts of the X-disease agent revealed mycoplasma-like organisms (MLO) only intercellularly and appressed to various organs in the haemocoele. No MLO were observed in uninjected M. fascifrons or those injected with extracts from non-infectious C. montanus. These results suggest that, despite multiplication of the X-agent in vivo. barriers in the gut and salivary glands prevent its transmission to plants by M. fascifrons.     

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.     

Graft and dodder transmission of phytoplasma affecting lily to experimental hosts

Experimental infection of Alstroemeria seedlings with naturally infected lily ‘Casablanca’ with stunting and flower bud deficiency phytoplasma resulted 3–4 weeks after top grafting in chlorotic and/or necrotic stripes, whitening of the leaves, shoot necrosis and die back. Flower discoloration or malformation were not observed. Attempts to transmit phytoplasma from naturally infected lily and experimentally infected Alstroemeria to Catharanthus roseus by top grafting resulted in stunted growth, dull yellowing and malformation of the leaves in 4–6 weeks. Some plants were temporary entirely vegetative and did not produce flowers. The periwinkle plants that were bridged by Cuscuta odorata from the diseased lilies and Alstroemerias showed similar symptoms as top-grafted ones. With the universal primer pairs rU3/fU5 specific PCR product with expected length ∼900 was amplified from samples collected from lilies with severe symptoms and top grafted test plants. All PCR products used for RFLP analysis after digestion with Alu I showed the same restriction profiles. Position of three obtained bands corresponded to the lengths of the DNA fragments of American aster yellows (AAY) phytoplasma group.     

Increased survival of Dalbulus maidis, a specialist on maize, on non-host plants infected with mollicute plant pathogens

The leafhopper Dalbulus maidis DeLong & Wolcott survived significantly longer on aster, Callistephus chinensis Nees, infected with any one of 3 strains of aster yellows (AY) mycoplasma-like organism (MLO) than on healthy asters. After 7 or more days on AY-diseased aster, females were conditioned to survive longer on healthy asters than were leafhoppers of the same age previously exposed only to maize. Females were also conditioned to survive longer on healthy aster by prior exposure to AY-MLO-infected celery (Apium graveolens L.). Males were not so conditioned. Leafhoppers injected with infectious extracts of AY-MLO dit not live longer on aster nor transmit the AY-MLO to aster. Conditioning on AY-diseased aster did not cause D. maidis to transmit AY-MLO and did not interfere with the transmission to maize of the mollicute (Spiroplasma kunkelii Whitcomb et al.) that causes corn stunt disease. Spiroplasma citri Saglio et al. infection of aster but not of turnip (Brassica rapa L.), Plantago major L. or periwinkle (Catharanthus roseus (L.)), improved the longevity of D. maidis on these plants and conditioned leafhoppers for enhanced subsequent survival on healthy asters.

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Résumé La cicadelle du maïs, D. maidis à survécu significativement plus longtemps sur aster (Callistephus chinensis Nees) contaminé par l'une des trois souches de l'agent mycoplasmique (MLO) de la jaunisse de l'aster (AY), que sur des asters sains. Après 7 jours ou plus sur des asters AY-MLO, les femelles (et non les mâles) étaient conditionnées de telle sorte qu'elles survivaient plus longtemps sur asters sains que des femelles du même âge précédemment sur maïs. Sur des céleris (Apium graveolens) atteints de AY, D. maidis a survécu plus longtemps que sur céleri sain, mais moins que sur aster AY. Des extraits, contaminés par AY injectés à D. maidis n'ont pas augmenté sa longévité sur aster, ni provoqué la transmission de AY-MLO. Le conditionnement sur aster AY n'a pas entrainé la transmission de AY-MLO par D. maidis, et n'a pas interferé avec son aptitude à transmettre l'agent du nanisme du maïs, Spiroplasma kunkelii. S. citri a aussi conditionné D. maidis sur aster, mais a été sans effet sur navet (Brassica rapa), sur plantain (Plantago major) et sur pervenche (Vinca).

     

Cultivation,serology, ultrastructure,and virus-like particles of spiroplasma 277F

Spiroplasma 277F, a helical, motile mycoplasma from rabbit ticks in Montana, was cloned and cultivated in liquid and solidified spiroplasma or mycoplasma media. Serum was required, glucose was fermented, and digitonin inhibited growth. Colonies of spiroplasma 277F possessed granular centers and were surrounded by smaller, subsurface “satellite” colonies. Cloned agent 277F was antigenically distinct from the suckling mouse cataract agent, the corn stunt organism, andSpiroplasma citri by growth inhibition and deformation tests, but exhibited weak cross-reactivity withS. citri in the precipitin ring tests. Although current passage levels did not cause cataracts in neonatal rats, kill embryonated hen's eggs, or cause bovine mastitis, definitive tests must await the availability of fresh isolates. Ultrastructurally, 277F closely resembledS. citri but displayed a system of 3-nm threadlike filaments in the exterior layer of its membranous covering. Two phagelike entities, similar to viruses associated withS. citri, were present.     

Scanning Electron Microscopy of the Influence of Fixation Vehicle Osmolality on Cell Morphology of Spiroplasma, Acholeplasma, and Mycoplasma spp. grown on Agar

Young Spiroplasma citri, corn stunt spiroplasma, and honey bee spiroplasma colonies fixed in 5% glutaraldehyde in M 199 cell culture medium with 0.25 M sucrose showed elongated mycelium-like cells which were sometimes branched or helical. In older colonies beaded chains and rounded bodies were formed. Fixation in 6 % glutaraldehyde in distilled water resulted in amorphous masses in which rounded bodies were present. The spiroplasma cells did not remain osmotically active after glutaraldehyde fixation. Acholeplasma laidlawii and Mycoplasma hyorhinis colonies fixed in glutaraldehyde with or without M 199 medium with 0.25 M sucrose showed little difference in cell morphology.     

Occurrence,Molecular Characterization and Vector Transmission of a Phytoplasma Associated with Rapeseed Phyllody in Iran

Symptoms of rapeseed phyllody were observed in rapeseed fields of Fars, Ghazvin, Isfahan, Kerman and Yazd provinces in Iran. Circulifer haematoceps leafhoppers testing positive for phytoplasma in polymerase chain reaction (PCR) successfully transmitted a rapeseed phyllody phytoplasma isolate from Zarghan (Fars province) to healthy rapeseed plants directly after collection in the field or after acquisition feeding on infected rapeseed in the greenhouse. The disease agent was transmitted by the same leafhopper from rape to periwinkle, sesame, stock, mustard, radish and rocket plants causing phytoplasma‐type symptoms in these plants. PCR assays using phytoplasma‐specific primer pair P1/P7 or nested PCR using primers P1/P7 followed by R16F2n/R2, amplified products of expected size (1.8 and 1.2 kbp, respectively) from symptomatic rapeseed plants and C. haematoceps specimens. Restriction fragment length polymorphism analysis of amplification products of nested PCR and putative restriction site analysis of 16S rRNA gene indicated the presence of aster yellows‐related phytoplasmas (16SrI‐B) in naturally and experimentally infected rapeseed plants and in samples of C. haematoceps collected in affected rapeseed fields. Sequence homology and phylogenetic analysis of 16S rRNA gene confirmed that the associated phytoplasma detected in Zarghan rapeseed plant is closer to the members of the subgroup 16SrI‐B than to other members of the AY group. This is the first report of natural occurrence and characterization of rapeseed phyllody phytoplasma, including its vector identification, in Iran.     

Continuous rearing of the aster leafhopper, Macrosteles fascifrons, on a chemically defined diet

A holidic diet for feeding the aster leafhopper, Macrosteles fascifrons, was formulated. The amino acids, B-vitamins, and sucrose are less concentrated than in aphid diets. Cholesterol, at 5 mg/ml, is required for the last ecdysis. Although leafhoppers reared on this diet have poorer survival and shorter life span than those reared on plants, they produce more progeny. Leafhoppers reared on this diet have completed the ninth generation and the culture is still thriving.     

Further studies on seed transmission in the ecology of some aphid-transmitted viruses

A small proportion (1–4%) of the seeds of Stellaria media extracted from fallow soil from three widely separated areas contained cucumber mosaic virus (CMV). S. media seeds buried for 21 months produced 5 % infected seedlings. S. media plants from Britain, N. America and Australia were least severely affected by the CMV strain obtained from their country of origin and showed more severe reactions when infected with two alien strains. Several weed species were experimentally infected with lettuce mosaic, turnip mosaic and cauliflower mosaic viruses but, although virus was detected in the seeds of some species, it was not transmitted to any of their seedlings.     

Transmission of broad bean stain virus and Echtes Ackerbohnenmosaik-Virus to field beans (Viciajaba) by weevils

Sitona lineatus and Apion vorax were the two most common species of weevil on field beans (Vicia faba minor) at Rothamsted between 1970 and 1974. In glasshouse tests, A. vorax was a much more efficient vector than 5. lineatus of broad bean stain virus (BBSV) and Echtes Ackerbohnenmosaik-Virus (EAMV), and both species transmitted EAMV more often than BBSV. Five other species of Apion transmitted the viruses infrequently or not at all. S. lineatus adults transmitted no more often after 8–16 days on infected plants than after 1–2 days. Some A. vorax adults transmitted EAMV, but not BBSV, after feeding on infected leaves for a few minutes. After 4 days on infected plants, A. vorax sometimes remained infective for the following 8 days. No A. vorax collected from woodland plants in spring was infective with BBSV or EAMV, but 4% from bean crops containing seed-borne infection carried BBSV and 17% carried EAMV. BBSV and EAMV were recovered from triturated weevils, but not from weevil haemolymph. Possibly the viruses are transmitted as contaminants of the mouthparts or by regurgitation during feeding, but A. vorax was observed to regurgitate only when anaesthetized. BBSV and EAMV were not transmitted by aphids (Aphis fabae and Acyrthosiphon pisum), nor by pollen beetles {Meligethes spp.). Field observations suggest that infected seed is the main source of BBSV and EAMV in spring-sown crops, and that crops grown from virus-free seed, and isolated from infected crops by 250–500 m, remain free of infection for most of the season.     

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.     

Transmission of pangola stunt virus by Sogatella kolophon

A fijivirus causing minor enations, stunting, leaf notching, seed head deformity and excess tillering of Digitaria spp. was transmitted from naturally infected Digitaria ciliaris to D. ciliaris, D. decumbens and Urochloa panicoides by the planthopper Sogatella kolophon; 40–70% of insects transmitted after an incubation period of 15–21 days, and continued to transmit for up to 30 more days until death. Symptoms developed in test plants 30–50 days after inoculation. Sogatella longifurcifera failed to transmit the virus under similar conditions. Virus particles were present in roots, stems and leaves of infected plants, and particles were found in regular arrays and random aggregates in fat body cells of transmitting insects. Viroplasm and tubular structures were associated with these particles. Extracts from infective insects contained 10-segment dsRNA when analysed by polyacrylamide gel electrophoresis. Virus survives over winter in planthoppers and D. ciliaris seedlings in frost-free areas of coastal Queensland, but infected plants have debilitated root systems and compete poorly with healthy plants.     

Growth inhibition of phytopathogenic spiroplasmas by membrane-interactive antimicrobial peptides Novispirin T7 and Caerin 1.1

Spiroplasma kunkelii and Spiroplasma citri, both helical-shaped cell wall-less bacteria, are the causative agents of corn stunt disease and citrus stubborn disease, respectively. Plants exhibiting natural resistance to these phytopathogenic spiroplasmas are currently lacking. Engineering artificial plant resistance using antimicrobial peptides (AMPs) has been conceived as a new approach to control the agronomically important spiroplasmal diseases. In preparation for such task, the present study focused on screening of AMPs that have potentials to curb the growth of S. kunkelii and S. citri. Four AMPs, including Novispirin T7, Caerin 1.1, Tricholongin and Dhvar4, were selected for in vitro growth inhibition test. A liquid assay method was developed for quick qualitative and quantitative evaluations of the AMPs. Our results demonstrated that Novispirin T7 and Caerin 1.1 were able to inhibit the growth of both phytopathogenic spiroplasmas with the efficacy comparable to that of tetracycline. Cell deformations were observed in spiroplasma cultures treated with these two peptides, indicating interactions of the AMPs with the spiroplasma cell membranes. The minimum inhibitory concentrations (MICs) of the AMPs against S. kunkelii and S. citri were determined.