Electron Microscopy and Molecular Characterization of Phytoplasmas Associated with Strawflower Yellows in the Czech Republic

Strawflower (Helichrysum bracteatum) with symptoms resembling those associated to phytoplasma infection were observed in several areas in the Czech Republic during the period 1994–2001. Plants with leaf bronzing, reddening and necrosis, proliferation of secondary shoots, flower abnormalities and dwarfing died in advanced stages of the disease. The disease incidence ranged from 2% to 70% and caused significant loss to the flower and seed production. Transmission electron microscopy showed phytoplasmas in sieve cells of affected plants, but not in healthy ones. Association of phytoplasmas with the disease was confirmed by polymerase chain reaction using phytoplasma universal ribosomal primers R16F2n/R16R2. An amplification product of the expected size (1.2 kb) was observed in all samples of the symptomatic strawflowers. The restriction profiles obtained following separate digestion with three endonucleases (AluI, HhaI, MseI) showed that phytoplasmas infecting strawflowers from different localities in the Czech Republic were uniform and undistinguishable from aster yellows (subgroup 16SrI-B). Sequence analysis of 1771 bp of the ribosomal operon amplified with primers P1/U3, R16F2n/R2 and 16R758/P7 indicated that the closest related phytoplasmas were those associated with 'Rehmannia glutinosa var. purpurea', both originating from Bohemia. This is the first report on the occurrence of a phytoplasma-associated disease of strawflower in the Czech Republic.     

Comparison of phytoplasmas infecting winter oilseed rape in the Czech Republic with Italian Brassica phytoplasmas and their relationship to the aster yellows group

Winter oilseed rape grown in several areas in South Bohemia showed symptoms of stunting, leaf reddening and extensive malformation of floral parts. Phytoplasmas were consistently observed by using electron microscopy only in phloem tissue of symptomatic plants. DNA isolated from infected and healthy control plants was used in PCR experiments. Primer pairs R16F2/R2, P1/P7 and rpF2/R2, amplifying, respectively, 16S rDNA, 16S rDNA plus spacer region and the beginning of the 23S and ribosomal protein gene L22 specific for phytoplasmas, were used. According to RFLP and sequence analyses of PCR products, the phytoplasma from rape was classified in the aster yellows phytoplasma group, subgroup 16SrI-B. The PCR products from the Czech phytoplasma-infected rape also had RFLP profiles identical to those of phytoplasma strains from Italian Brassica . This first molecular characterization of phytoplasmas infecting rape compared with strains from Brassica does not, however, clearly indicate differences among isolates of the same 16SrI-B subgroup. Further studies on other chromosomal DNA portions could help the research on host specificity or on geographical distribution of these phytoplasmas.     

Association of aster yellows subgroup 16SrI-B phytoplasmas with a disease of Rehmannia glutinosa var. purpurea

A new phytoplasma disease of Rehmannia glutinosa var. purpurea was observed in the Czech Republic in 1998. Infected plants showing severely proliferating shoots, leaves reduced in size with vein clearing and chlorosis, shortened internodes and virescent petals died in advanced stages of the disease. Electron microscopy examination of the ultra-thin sections revealed the presence of numerous polymorphic bodies in phloem tissue of leaf midribs and petioles. The disease was successfully transmitted from infected plant via a dodder bridge into periwinkle ( Catharanthus roseus ). The phytoplasma aetiology of this disease was further confirmed by polymerase chain reaction (PCR) using universal primers R16F2/R16R2. Restriction fragment length polymorphism (RFLP) analysis of amplification products indicated the presence of aster yellows related phytoplasmas (16SrI-B) in naturally infected samples of R. glutinosa var . purpurea and in symptomatic periwinkle after dodder transmission of the agent. A comparison of the amplified sequence with 17 sequences available in the GenBank confirmed the classification of the phytoplasma in the subgroup 16SrI-B. This is the first report of natural occurrence of phytoplasma-associated disease in R. glutinosa var. purpurea.     

An Antibody Against the SecA Membrane Protein of One Phytoplasma Reacts with Those of Phylogenetically Different Phytoplasmas

ABSTRACT Antisera raised against phloem-limited phytoplasmas generally react only with the phytoplasma strain used to produce the antigen. There is a need for an antiserum that reacts with a variety of phytoplasmas. Here, we show that an antiserum raised against the SecA membrane protein of onion yellows phytoplasma, which belongs to the aster yellows 16S-group, detected eight phytoplasma strains from four distinct 16S-groups (aster yellows, western X, rice yellow dwarf, and elm yellows). In immunoblots, approximately 96-kDa SecA protein was detected in plants infected with each of the eight phytoplasmas. Immunohistochemical staining of thin sections prepared from infected plants was localized in phloem tissues. This antiserum should be useful in the detection and histopathological analysis of a wide range of phytoplasmas.     

Molecular and symptom analyses of phytoplasma strains from lettuce reveal a diverse population

ABSTRACT Epidemics of aster yellows in lettuce in Ohio are caused by at least seven distinct phytoplasma strains in the aster yellows (AY) group. Five of the strains are newly reported: AY-BW, AY-WB, AY-BD3, AY-SS, and AY-SG. All seven strains were characterized based on symptoms in aster and lettuce, and by polymerase chain reaction (PCR). Strain AY-BD2 (formerly 'Bolt') causes yellowing and leaf distortion in lettuce and bolting in aster, whereas strain AY-S (formerly 'Severe') causes stunting, leaf clustering, and phyllody. Strain AY-WB causes yellowing and wilting in lettuce and witches'-broom in aster. Strain AY-SG induces horizontal growth in lettuce and aster plants. Strain AY-BW causes chlorosis of emerging leaves and abnormally upright growth of leaf petioles. AY-SS causes symptoms similar to those caused by AY-S but has a different PCR-restriction fragment length polymorphism (RFLP) banding pattern. Strains AY-BD2 and AY-BD-3 cause mild leaf and stem distortion in lettuce but are differentiated by PCR-RFLP. All phytoplasma strains collected from lettuce in Ohio belong to the 16SrI group. AY-WB belongs to the 16SrI-A subgroup and the other six belong to the 16SrI-B subgroup. Five of the seven strains were distinguished from each other by primer typing. The results of phylogenetic analyses of sequences of the 16S rRNA genes were basically consistent with the classification based on PCR-RFLP, in which AY-WB clustered with phytoplasmas of the 16rIA subgroup and the other Ohio lettuce strains clustered with phytoplasmas in the 16SrI-B subgroup.     

Reclassification of aster yellows group phytoplasmas in Korea

Aster yellows group phytoplasmas were reclassified by analysis of the 16S rRNA gene sequence, their phylogeny and the presence of interoperon heterogeneity. Nine phytoplasmas were classified into subgroups 16SrI-B and 16SrI-D using the 16S rRNA gene sequence. Then, based on the presence of interoperon heterogeneity, subgroup 16SrI-B phytoplasmas were differentiated into three subunits as 16SrI-B(a): mulberry dwarf, sumac witches’ broom and porcelain vine witches’ broom; 16SrI-B(b): angustata ash witches’ broom and Japanese spurge yellows; and 16SrI-B(c): onion yellow dwarf, water dropwort witches’ broom and hare’s ear yellow dwarf phytoplasma.     

Ecological implications from a molecular analysis of phytoplasmas involved in an aster yellows epidemic in various crops in Texas

ABSTRACT In the spring of 2000, an aster yellows (AY) epidemic occurred in carrot crops in the Winter Garden region of southwestern Texas. A survey revealed that vegetable crops, including cabbage, onion, parsley, and dill, and some weeds also were infected by AY phytoplasmas. Nested polymerase chain reaction (PCR) and restriction fragment length polymorphism analysis of PCR-amplified phytoplasma 16S rDNA were employed for the detection and identification of phytoplasmas associated with these crops and weeds. Phytoplasmas belonging to two subgroups, 16SrI-A and 16SrI-B, in the AY group (16SrI), were predominantly detected in infected plants. Carrot, parsley, and dill were infected with both subgroups. Onion and three species of weeds (prickly lettuce, lazy daisy, and false ragweed) were predominantly or exclusively infected by subgroup 16SrI-A phytoplasma strains, while cabbage was infected by subgroup 16SrI-B phytoplasmas. Both types of phytoplasmas were detected in three leafhopper species, Macrosteles fascifrons, Scaphytopius irroratus, and Ceratagallia abrupta, commonly present in this region during the period of the epidemic. Mixed infections were very common in individual carrot, parsley, and dill plants and in individual leafhoppers. Sequence and phylogenetic analyses of 16S rDNA and ribosomal protein (rp) gene sequences indicated that phytoplasma strains within subgroup 16SrI-A or subgroup 16SrI-B, detected in various plant species and putative insect vectors, were highly homogeneous. However, based on rp sequences, two rpI subgroups were identified within the subgroup 16SrI-A strain cluster. The majority of subgroup 16SrI-A phytoplasma strains were classified as rp subgroup rpI-A, but phytoplasma strains detected in one onion sample and two leafhoppers (M. fascifrons and C. abrupta) were different and classified as a new rp subgroup, rpI-N. The degree of genetic homogeneity of the phytoplasmas involved in the epidemic suggested that the phytoplasmas came from the same pool and that all three leafhopper species may have been involved in the epidemic. The different phytoplasma population profiles present in various crops may be attributed to the ecological constraints as a result of the vector-phytoplasma-plant three-way interaction.     

Molecular characterization of diverse phytoplasmas of subgroups 16SrI-A, 16SrI-B, 16SrI-L, and 16SrI-M infecting ornamental plants in Lithuania

Trade in ornamental plant species comprises a significant segment in the economies of countries in Europe, North America and Asia. Since the quality of ornamental plants is adversely affected by diseases attributed to phytoplasmas, we surveyed plant collections in botanical gardens and floriculture farms in Lithuania for phytoplasmal diseases. Seventeen ornamental species belonging to nine plant families exhibited disease symptoms including general yellowing and stunting, proliferation of shoots, phyllody, virescence and reduced size of flowers, and reddening of leaves. Analysis of the phytoplasmal 16S rRNA gene sequences amplified by PCR revealed that the plants were infected by phytoplasmas belonging to four distinct subgroups (16SrI-A, 16SrI-B, 16SrI-L, and 16SrI-M) of group 16SrI (aster yellows phytoplasma group) and indicated the presence of sequence-heterogeneous 16S rRNA genes in newly recognized strains belonging to subgroups 16Sr-L and 16SrI-M. Infections by these diverse phytoplasmas in a wide array of plant species and families suggests that unidentified, polyphagous insect vectors may actively transmit phytoplasmas threatening the Baltic region's ornamental plant industry.     

Detection and identification of phytoplasmas in yellows-diseased weeds in Italy

Yellows-diseased plants of Crepis setosa (hawksbeard), Knautia arvensis (field scabious), Convolvulus arvensis (field bindweed), Picris echioides (bristly oxtongue), Echium vulgare (blueweed) and Calendula officinalis (pot marigold) collected in central and southern Italy were examined for phytoplasma infection by means of polymerase chain reaction (PCR) technology using universal phytoplasma primers directed to ribosomal sequences. The detected phytoplasmas were characterized and differentiated using restriction fragment length polymorphism analysis of PCR-amplified DNA. The phytoplasma detected in diseased pot marigold plants was identified as a member of the aster yellows group and proved indistinguishable from a strain of the American aster yellows phytoplasma. The phytoplasma identified in diseased field bindweed plants is a putative new type of the stolbur group that differed from the typical stolbur phytoplasma. Phytoplasmas detected in diseased hawksbeard, blueweed and field scabious plants are all putative new members of the sugarcane white leaf group while the phytoplasma detected in diseased bristly oxtongue plants represents a new member of the faba bean phyllody group. For hawksbeard and field scabious this is the first report on the occurrence of phytoplasma diseases, whereas phytoplasmas infecting bristly oxtongue and blueweed have never been characterized before.     

Electron microscopy and molecular identification of phytoplasmas associated with strawberry green petals in the Czech Republic

The presence of phytoplasma inFragaria ananassa x Duch cv Senga Sengana showing strawberry green petals symptoms was observed by electron microscopy of phloem tissue. No phytoplasmas were found in asymptomatic strawberry plants used as controls. Nucleic acids extracted from these plants were used in nested-PCR assays with primers amplifying 16S rRNA sequences specifie for phytoplasmas. Bands of 1.2 kb were obtained and the subsequent nested-PCR with specific primers and RFLP analyses allowed to classify the detected phytoplasmas in the aster yellows group (16SrI). They belonged to the subgroup I-C of which type strain is clover phyllody phytoplasma.     

Phylogenetic analysis of elongation factor Tu gene of phytoplasmas from Japan

The elongation factor Tu (tuf) gene from nine Japan phytoplasma isolates was amplified with the polymerase chain reaction, and the DNA sequences of the tuf gene were determined. The tuf gene from 14 phytoplasma isolates, including reference isolates and other bacteria, were phylogenetically analyzed. A nucleotide sequence of the tuf gene among seven aster yellows group (16Sr I-B and I-D) phytoplasmas had 97%–100% similarity, and the tuf gene of two phytoplasmas of the X-disease group (16Sr III-B) had 99% similarity. The tuf genes had lower homology than did the 16S rRNA gene in the phytoplasma groups. A phylogenetic tree of amino acid sequences of the tuf gene was nearly equal to that of the 16S rRNA gene but differed somewhat from the tree based on the 16S rRNA gene in that paulownia witches broom (PaW: 16Sr I-D) and American aster yellows (AAY: 16Sr I-B) were in a subclade.The nucleotide sequence data reported are available in the DDBJ/EMBL/GenBank databases under the accession numbers AB095495, AB095667, AB095668, AB095669, AB095670, AB095671, AB095672, AB095673 and AB095674     

Association of 'Candidatus Phytoplasma australiense' with green petal and lethal yellows diseases in strawberry

The identity of phytoplasmas detected in strawberry plants with green petal (SGP) and lethal yellows (SLY) diseases was determined by RFLP analysis of the 16S rRNA gene and adjacent spacer region (SR). RFLP and sequence comparisons indicated that the phytoplasmas associated with SGP and SLY were indistinguishable and were most closely related to ' Candidatus Phytoplasma australiense', the phytoplasma associated with Australian grapevine yellows, papaya dieback and Phormium yellow leaf diseases. This taxon lies within the aster yellows strain cluster. Primers based on the phytoplasma tuf gene, which amplify only members of the AY strain cluster, amplified a DNA product from the SGP and SLY phytoplasmas. Primers deduced from the 16S rRNA/SR of P. australiense that amplify only members of this taxon amplified rDNA sequences from the SGP and SLY phytoplasmas. Primers that selectively amplify members of the faba bean phyllody (FBP) phytoplasma group, the most commonly occurring phytoplasma group in Australia, did not amplify rDNA from the SGP and SLY phytoplasmas.     

First report of a 16SrIII-B subgroup phytoplasma associated with leaf reddening, virescence and phyllody of purple coneflower

Purple coneflower plants showing leaf reddening and flower abnormalities were observed in South Bohemia (Czech Republic). Transmission electron microscopy observations showed phytoplasmas in sieve cells of symptomatic plants but not in healthy ones. Polymerase chain reactions with universal and group specific phytoplasma primers followed by restriction fragment length polymorphism analyses of 16S rDNA allowed us to classify the detected phytoplasmas into the X-disease group, ribosomal subgroup 16SrIII-B. Sequence analyses of the 16S-23S ribosomal operon (1684 bp), ribosomal protein L15, and protein translocase genes (1566 bp) confirmed the closest relationship with phytoplasmas belonging to the 16SrIII ribosomal group, specifically the 16SrIII-B subgroup. The current study reports purple coneflower as a new host for the X-disease phytoplasma group in the Czech Republic and worldwide.     

‘Candidatus Phytoplasma australiense’ is the phytoplasma associated with Australian grapevine yellows, papaya dieback and Phormium yellow leaf diseases

Sequence comparisons and phylogenetic analysis of the 16S rRNA genes and the 16S/23S spacer regions of the phytoplasmas associated with Australian grapevine yellows, papaya dieback and Phormium yellow leaf diseases revealed minimal nucleotide differences between them resulting in the formation of a monophyletic group. Therefore, along with Australian grapevine yellows, the phytoplasmas associated with Phormium yellow leaf and papaya dieback should also be considered as Candidatus Phytoplasma australiense.     

Characterization and classification of phytoplasmas from wild and cultivated plants by RFLP and sequence analysis of ribosomal DNA

Restriction fragment length polymorphism and sequence analysis of PCR-amplified ribosomal DNA were used to identify and classify phytoplasmas associated with diseases of various wild and cultivated plants. The diseases examined were either not known before or the presumable causal agents were not yet identified and characterized or were only known from other geographic areas. New diseases examined were those causing virescence and phyllody of Bunias orientalis and Cardaria draba. Both were associated with strains of the aster yellows phytoplasma. The same type of aster yellows phytoplasma was also found to be associated with yellows and phyllody diseases of Portulaca oleracea, Stellaria media, Daucus carota ssp. sativus, and Cyclamen persicum. In German and French DNA samples from diseased Trifolium repens, the clover phyllody phytoplasma was identified, which could clearly be distinguished from other phytoplasmas of the aster yellows group. Strains of the stolbur phytoplasma were detected in big bud-affected tomatoes and almost exclusively in Convolvulus arvensis. In Cirsium arvense and Picris echioides two distinct phytoplasmas were identified which showed relationship to the sugarcane white leaf phytoplasma group but may represent a new group or subgroup. In Conyza (syn.: Erigeron) canadensis a phytoplasma of the X-disease group was detected. A strain from Gossypium hirsutum showed the same restriction profiles as the faba bean phyllody phytoplasma.     

Distinctions between phytoplasmas at the subgroup level detected by heteroduplex mobility assay

A total of 62 phytoplasma isolates were collected from North America, Europe and Asia and analysed by heteroduplex mobility assay (HMA) of the 16/23S spacer region amplified by the polymerase chain reaction. The results revealed wide genetic diversity among the phytoplasmas studied and a number of new phytoplasma strains were identified from known or new plant hosts in Alberta, Canada. Two distinctive subgroups were revealed by HMA in phytoplasmas associated with canola yellows, Chinese aster yellows, dandelion yellows and monarda yellows. In Alberta, two subgroups of the aster yellows group of phytoplasmas, I-A and I-B, were prevalent in naturally infected field crops and ornamentals in open gardens. The results indicated that HMA is a simple, but rapid and accurate, alternative method for the detection and estimation of genetic divergence of phytoplasmas when finer molecular characterization of phytoplasmas is required at the subgroup level.     

Note: Molecular identification of ‘Candidatus phytoplasma asteris’ inducing histological anomalies inSilene nicaeensis

Numerous plants ofSilene nicaeensis having symptoms resembling those associated with the presence of phytoplasmas were observed in an extensive coastal area in the south of Italy. Microscopic observation showed histological abnormalities in the organization of tissues in symptomatic plants, and molecular tests, including PCR/RFLP analyses and nucleic acid sequencing, revealed the presence of phytoplasmas belonging to the aster yellows group (‘Candidatus phytoplasma asteris’). This is the first report of phytoplasma infection inS. nicaeensis, a wild species that colonizes the Calabrian coast. http://www.phytoparasitica.org posting June 12, 2008     

菊花绿变病植原体在中国的发生及分子鉴定

对内蒙古农业大学校园内表现花器绿变症状的菊花样品进行采集和DNA提取,应用植原体16S rRNA基因和rp基因的引物进行巢式PCR扩增,从感病样品中分别扩增得到了长度均约为1.2 kb的片段。序列一致性分析表明,菊花绿变植原体16S rRNA基因与翠菊黄化植原体匈牙利风信子株系(GenBank登录号MN080271)、印度玉米株系(KY565571)、印度繁缕株系(KC623537)和印度马铃薯株系(KC312703)的核酸一致性最高,为99.9%,rp基因序列与翠菊黄化植原体立陶宛洋葱株系(GU228514)的核酸一致性最高,为99.8%。基于16S rRNA基因和rp基因构建系统进化树时发现,菊花绿变植原体均与16SrI-B亚组成员聚为一起。16S rRNA基因相似性系数分析表明,菊花绿变植原体与洋葱黄化植原体(AP006628)的相似性系数最高为1.00,洋葱黄化植原体(AP006628)在分类上属于16SrI-B亚组。因此,我们可以确定该菊花绿变植原体属于16SrI-B亚组。这是我国首次报道菊花绿变病的发生。     

Use of heteroduplex mobility assay for identification and differentiation of phytoplasmas in the aster yellows group and the clover proliferation group

ABSTRACT This paper describes the identification and differentiation of phytoplasmas by a highly sensitive diagnostic technique, DNA heteroduplex mobility assay (HMA). Closely related phytoplasma isolates of clover proliferation (CP), potato witches'-broom (PWB), and alfalfa witches'-broom (AWB) were collected from the field from 1990 to 1999. The entire 16S rRNA gene and 16/23S spacer region were amplified by polymerase chain reaction (PCR) from the field samples and standard CP, PWB, and AWB phytoplasmas and were subjected to restriction fragment length polymorphism (RFLP) analysis and HMA. Two subgroups (I and II) of phytoplasmas in the CP group were identified by HMA but not by RFLP analysis. The results were confirmed by 16/23S spacer region sequence data analysis. After HMA analyses of the PCR-amplified 16/23S spacer region, 14 phytoplasma isolates from field samples were classified into two aster yellows subgroups: subgroup I, phytoplasma isolates from China aster (Callistephus chinensis) yellows, French marigold (Tagetes patula) yellows, cosmos (Cosmos bipinnatus cv. Dazzler) yellows, clarkia (Clarkia unguiculata) yellows, California poppy (Eschscholzia californica cv. Tai Silk) yellows, monarda (Monarda fistulosa) yellows, and strawflower (Helichrysum bracteatum) yellows; and subgroup II, phytoplasma isolates from zinnia (Zinnia elegans cv. Dahlia Flower) yellows, Queen-Annes-Lace (Daucus carota) yellows, scabiosa (Scabiosa atropurpurea cv. Giant Imperial) yellows, Swan River daisy (Brachycombe multifida cv. Misty Pink) yellows, pot marigold (Calendula officinalis) yellows, purple coneflower (Echinacea purpurea) yellows, and feverfew (Chrysanthemum parthenium) yellows. The results indicate that HMA is a simple, rapid, highly sensitive and accurate method not only for identifying and classifying phytoplasmas but also for studying the molecular epidemiology of phytoplasmas.