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.     

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.     

A third DNA polymerase from Spiroplasma citri and two other spiroplasmas.

Recently, two DNA polymerases (ScA and ScB) were isolated and characterized from Spiroplasma citri. We now have found a third DNA polymerase (ScC) not only in S. citri but also in the serologically related honeybee spiroplasma BC3 and the unrelated flower spiroplasma BNR1. Enzyme ScC is N-ethylmaleimide (NEM) sensitive. The three DNA polymerases from the honeybee spiroplasma seem to be similar to the respective enzymes of S. citri. However, whereas the NEM-resistant enzyme ScA from S. citri and that from the BC3 honeybee spiroplasma are retained on DEAE-cellulose and require 0.09 M KCl for elution, the NEM-resistant enzyme A from the flower spiroplasma BNR1 is not retained.     

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.     

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.     

Spiroplasmas from coleopterous insects: New ecological dimensions

The genusSpiroplasma (helical wall-less prokaryotes) is a recently described group of microorganisms that cause disease in plants, arthropods, and experimentally, in vertebrates. Two spiroplasmas from beetles have now been discovered in a search for microorganisms suitable for biological control of economically important coleopterous insects. Colorado potato beetles (CPB) infected with spiroplasma were commonly found on potato and other solanaceous plants in Maryland. Although this spiroplasma occurred in high concentration in gut fluids and sputum, it could not be cultivated in conventional spiroplasma media. However, another spiroplasma (CN-5 and related strains) reported here to occur commonly in association with larvae and adults of the green June beetle,Cotinus nitida, could be cultivated readily in the SM-1 formulation and several other conventional spiroplasma media. The CN-5 spiroplasma was serologically distinct from representative members of all 8 major groups now recognized. Thus, it represents a ninth major spiroplasma serogroup (IX), and can be considered to be an unnamed species. The CPB spiroplasma is apparently maintained in plant surface-insect gut cycles, but details of maintenance of the CN-5 spiroplasma are incompletely understood. Isolation of CN-5 spiroplasma from soil in which host larvae had fed suggests that transmission of this agent may occur in the soil. Both CN-5 and CPB spiroplasmas exhibited unusually active translational motility in natural fluids, and CN-5 organisms exhibited such motility in culture media. Although we have no evidence that either spiroplasma is pathogenic to its usual host, the pathogenicity of spiroplasmas to many hosts, including the beetle,Melolontha melolontha, suggests possible application for biological control.     

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.     

Characterization and taxonomic status of tick spiroplasmas: a review

Three serologically distinct groups of spiroplasmas have been recovered from ticks. Spiroplasma mirum strains (from rabbit ticks, Haemaphysalis leporispalustris) and Y32 group (VI) spiroplasmas (from Ixodes pacificus) are the only spiroplasmas to have a clear association with these arthropods. Group (VI) spiroplasmas are distinguished by an unusual nonhelical morphology and their capacity to hemadsorb guinea pig erythrocytes. S. mirum strains are unique in their ability to induce cataracts or lethal brain infections in a number of young vertebrates and in their virulence for the chick embryo. The 277F spiroplasma, while initially recovered from a pool of rabbit ticks (H. leporispalustris), is related by certain serological and genetic properties to spiroplasmas in the S. citri complex (serogroup I). These relationships suggest that the 277F spiroplasma may not be a natural inhabitant of the rabbit tick.     

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.     

Gene disruption through homologous recombination in Spiroplasma citri: an scm1-disrupted motility mutant is pathogenic

To determine whether homologous recombination could be used to inactivate selected genes in Spiroplasma citri, plasmid constructs were designed to disrupt the motility gene scm1. An internal scm1 gene fragment was inserted into plasmid pKT1, which replicates in Escherichia coli but not in S. citri, and into the S. citri oriC plasmid pBOT1, which replicates in spiroplasma cells as well as in E. coli. Electrotransformation of S. citri with the nonreplicative, recombinant plasmid pKTM1 yielded no transformants. In contrast, spiroplasmal transformants were obtained with the replicative, pBOT1-derived plasmid pCJ32. During passaging of the transformants, the plasmid was found to integrate into the chromosome by homologous recombination either at the oriC region or at the scm1 gene. In the latter case, plasmid integration by a single crossover between the scm1 gene fragment carried by the plasmid and the full-length scm1 gene carried by the chromosome led to a nonmotile phenotype. Transmission of the scm1-disrupted mutant to periwinkle (Catharanthus roseus) plants through injection into the leafhopper vector (Circulifer haematoceps) showed that the motility mutant multiplied in the insects and was efficiently transmitted to plants, in which it induced symptoms similarly to the wild-type S. citri strain. These results suggest that the spiroplasmal motility may not be essential for pathogenicity and that, more broadly, the S. citri oriC plasmids can be considered promising tools for specific gene disruption by promoting homologous recombination in S. citri, a mollicute which probably lacks a functional RecA protein.     

Mycoplasmas, plants, insect vectors: a matrimonial triangle

Plant pathogenic mycoplasmas were discovered by electron microscopy, in 1967, long after the discovery and culture in 1898 of the first pathogenic mycoplasma of animal origin, Mycoplasma mycoides. Mycoplasmas are Eubacteria of the class Mollicutes, a group of organisms phylogenetically related to Gram-positive bacteria. Their more characteristic features reside in the small size of their genomes, the low guanine (G) plus cytosine (C) content of their genomic DNA and the lack of a cell wall. Plant pathogenic mycoplasmas are responsible for several hundred diseases and belong to two groups: the phytoplasmas and the spiroplasmas. The phytoplasmas (previously called MLOs, for mycoplasma like organisms) were discovered first; they are pleiomorphic, and have so far resisted in vitro cultivation. Phytoplasmas represent the largest group of plant pathogenic Mollicutes. Only three plant pathogenic spiroplasmas are known today. Spiroplasma citri, the agent of citrus stubborn was discovered and cultured in 1970 and shown to be helical and motile. S. kunkelii is the causal agent of corn stunt. S. phoeniceum, responsible for periwinkle yellows, was discovered in Syria. There are many other spiroplasmas associated with insects and ticks. Plant pathogenic mycoplasmas are restricted to the phloem sieve tubes in which circulates the photosynthetically-enriched sap, the food for many phloem-feeding insects (aphids, leafhoppers, psyllids, etc.). Interestingly, phytopathogenic mycoplasmas are very specifically transmitted by leafhoppers or psyllid species. In this paper, the most recent knowledge on phytopathogenic mycoplasmas in relation with their insect and plant habitats is presented as well as the experiments carried out to control plant mycoplasma diseases, by expression of mycoplasma-directed-antibodies in plants (plantibodies).     

Biological and molecular evidence for the transmission of aster yellows phytoplasma to French marigold (Tagetes patula) by the flatid planthopper Metcalfa pruinosa

Aster yellows (AY) phytoplasmas (Candidatus Phytoplasma asteris) are associated with a number of plant diseases throughout the world. Several insect vectors are responsible for spreading AY diseases resulting in wide distribution and low host specificity. Because the role of sucking insects as vectors of phytoplasmas is widely documented, and the citrus flatid planthopper Metcalfa pruinosa is a phloem feeder, it has been incriminated as a possible vector of phytoplasmas. However, its ability to transfer phytoplasma has not been confirmed. The present work shows that M. pruinosa (Hemiptera: Flatidae), a polyphagous planthopper, is able to vector Ca. P. asteris to French marigold (Tagetes patula). Transmission experiments were conducted in 2017 and 2018 in central Hungary by two approaches: (a) AY-infected M. pruinosa were collected from an area with severe incidence of the disease on T. patula and caged on test plants for an inoculation-access period of 2 weeks, and (b) presumably phytoplasma-free insects were collected from apparently healthy grapevines (Vitis vinifera L.) and fed on AY-infected T. patula plants for 2 weeks prior to being caged on test plants. AY disease symptoms developed on 4 out of 10 and 10 out of 15 test plants, respectively. All phytoplasma-positive marigold and M. pruinosa samples showed identical RFLP patterns and shared 100% 16S rDNA sequence identity with each other and with the aster yellows phytoplasma strain AJ33 (GenBank accession number MK992774). These results indicated that the phytoplasma belonged to the phytoplasma subgroup 16SrI-B Ca. P. asteris. Therefore, the work presented here provides experimental evidence that M. pruinosa is a vector of a 16SrI-B subgroup phytoplasma to T. patula.     

Isolation, characterization, and complementation of a motility mutant of Spiroplasma citri.

The helical mollicute Spiroplasma citri, when growing on low-agar medium, forms fuzzy colonies with occasional surrounding satellite colonies due to the ability of the spiroplasmal cells to move through the agar matrix. In liquid medium, these helical organisms flex, twist, and rotate rapidly. By using Tn4001 insertion mutagenesis, a motility mutant was isolated on the basis of its nondiffuse, sharp-edged colonies. Dark-field microscopy observations revealed that the organism flexed at a low frequency and had lost the ability to rotate about the helix axis. In this mutant, the transposon was shown to be inserted into an open reading frame encoding a putative polypeptide of 409 amino acids for which no significant homology with known proteins was found. The corresponding gene, named scm1, was recovered from the wild-type strain and introduced into the motility mutant by using the S. citri oriC plasmid pBOT1 as the vector. The appearance of fuzzy colonies and the observation that spiroplasma cells displayed rotatory and flexional movements showed the motile phenotype to be restored in the spiroplasmal transformants. The functional complementation of the motility mutant proves the scm1 gene product to be involved in the motility mechanism of S. citri.     

Comparison of the membrane composition of Spiroplasma citri and the corn stunt Spiroplasma.

Components of membranes isolated from Spiroplasma citri and corn stunt spiroplasma grown at 28 degrees C were analyzed. On a protein basis, lipid phosphorus was lower and cholesterol was higher in S. citri. Only minor differences between the two species were found in fatty acid composition, reduced nicotinamide adenine dinucleotide diaphorase, and adenosine triphosphatase.     

Selection and characterization of Spiroplasma citri mutants by random transposome mutagenesis

Phytopathogenic spiroplasmas can multiply in vascular plants and insects. A deeper understanding of this dual-host life could be furthered through the identification by random mutagenesis of spiroplasma genes required. The ability of the EZ::TN? Tnp transposome? system to create random insertional mutations in the genome of Spiroplasma citri was evaluated. The efficiency of electroporation-mediated transformation of S. citri BR3-3X averaged 28.8 CFUs/ng transposome for 10(9) spiroplasma cells. Many transformants appearing on the selection plates were growth impaired when transferred to broth. Altering broth composition in various ways did not improve their growth. However, placing colonies into a small broth volume resulted in robust growth and successful subsequent passages of a subset of transformants. PCR using primers for the dihydrofolate reductase gene confirmed the transposon's presence in the genomes of selected transformants. Southern blot hybridization and nucleotide sequencing suggested that insertion was random within the chromosome and usually at single sites. The insertions were stable. Growth rates of all transformants were lower than that of the wild-type S. citri, but none lost the ability to adhere to a Circulifer tenellus (CT-1) cell line. The EZ::TN? Tnp transposome? system represents an additional tool for genetic manipulation of the fastidious spiroplasmas.     

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.     

Characterization and molecular methods for detection of a novel spiroplasma pathogenic to Penaeus vannamei

Traditionally, Spiroplasma spp. have only been isolated from the surfaces of flowers and other plant parts, from the guts and hemolymph of various insects, and from vascular plant fluids (phloem sap) and insects that feed on these fluids. In this article, we report the first pathogenic spiroplasma to be discovered in shrimp and the results of its characterization through histological evaluation, in situ hybridization assays, transmission electron microscopy, 16S rRNA sequence homology, and injection infectivity studies. In addition, molecular methods are described that were developed for the detection of this microorganism, which was determined to be the causative disease agent in Colombian farm-raised Penaeus vannamei suffering from high mortalities. Using standard histological methods and in situ hybridization assays, it was confirmed that P. vannamei was infected with this pathogenic spiroplasma. Histological analysis revealed systemic inflammatory reactions in affected organs/tissues. In an attempt to identify the bacteria, frozen infected P. vannamei samples, from the initial epizootic, were used to sequence the 16S rRNA gene and develop molecular detection methods. The 16S rRNA gene was amplified by PCR and then sequenced. The sequence data were analyzed using the GenBank BLAST search and the results revealed a 98% homology with Spiroplasma citri, a pathogen of citrus trees. The 16S rRNA sequence data were evaluated for development of unique PCR primers to the putative spiroplasma. Using PCR primers developed for the spiralin gene of Spiroplasma spp., a digoxigenin-labeled probe was developed and tested. This probe was species-specific, with no positive reactions or cross-reactivity occurring with other bacterial samples tested in this format.     

Antigenic relatedness between the spiralins of Spiroplasma citri and Spiroplasma melliferum.

Four spiralins were compared by rocket immunoelectrophoresis, quantitative immunoblotting techniques, and the spiroplasma deformation test with the use of antispiralin (polyclonal) monospecific antibodies. This investigation revealed that the spiralins of Spiroplasma citri and S. melliferum are antigenically related and that probably no more than two epitopes simultaneously saturable with antibodies are shared by the two proteins. One at least of these epitopes is accessible to antibodies on the spiroplasma cell surface.     

Amplification of plasmid DNA to detect plant pathogenic mycoplasmalike organisms

The polymerase chain reaction (PCR) was employed to develop a specific assay for plant pathogenic mycoplasmalike organisms (MLOs). A cloned fragment of a plasmid from a severe strain of western aster yellows (AY)-MLO was sequenced to identify oligonucleotide primers for PCR. Amplified DNA fragments of the predicted size were obtained from DNA extracted from plants and insects infected with pear decline MLO, beet leafhopper-transmitted virescence agent, elm yellows MLO and several AY-MLO strains. No amplification occurred from healthy leafhopper or plant DNA. The PCR-based assay was over 500 times more sensitive than a _tilized_tion-based assay which _tilized a cloned AY plasmid fragment as a probe. With the PCR-based assay, MLOs could be detected using DNA samples of leafhoppers that were only crushed and boiled in buffer. Amplification of the target DNA was confirmed by digestion of the PCR product with Mbo I which yielded predicted sized fragments for all MLO strains except Bradford AY and eastern AY. Sequencing the PCR product from elm yellows and eastern AY-MLOs revealed greater than 90% homology, and the failure to restrict the PCR product with Mbo I was due to a single base change in the restriction endonuclease site. The ability of the assay to detect a wide range of MLOs with minimal sample preparation and high sensitivity will be useful in epidemiological studies of MLO-caused diseases.     

Cytopathology of Plants Infected with Viruses. Ultrastructure of the Leaf Cells of Cereals Affected by Cereal Rhabdoviruses

Ultrathin sections of oat, wheat, and ryegrass leaves from healthy plants and plants infected with rhabdoviruses by leafhoppers Laodelphax striatellusFallen were studied under the electron microscope. The bacilliform virions often surrounded by endoplasmic reticulum (ER) membranes, viroplasm, and tubular structures conforming, in diameter and structure, to the rhabdovirion nucleocapsid were observed in the cytoplasm of leaf cells of the diseased plants. The cereal pseudorosette virus [(165–200) × (63–70) nm, CPV] is the causative agent of the disease of cereals in Siberia. The mycoplasma-like organisms were found in the phloem cells of plants infected with CPV. The cereal mosaic virus [(360–420) × (56–64) nm, CMV] is the causative agent of the disease of cereals in the Russian Far East. CMV appears to be a strain of the northern cereal mosaic virus.