Phylogenetic relationships among Flavescence dorée strains and related phytoplasmas determined by heteroduplex mobility assay and sequence of ribosomal and Nonribosomal DNA

Heteroduplex mobility assay (HMA) and DNA sequencing were performed on Flavescence dorée (FD) phytoplasma strains and related phytoplasmas belonging to the elm yellows group. Part of the ribosomal RNA gene operon and a nonribosomal DNA region were utilized for phylogenetic analyses. Two FD strains, FD92 and FD-D, detected in France and Italy, respectively, were identical in both DNA fragments, confirming previous results. Other FD strains were all very similar and most closely resembled ALY, an Italian alder phytoplasma. Phytoplasmas associated with German Palatinate grapevine yellows were shown to form a distinct subcluster, also different from the elm yellows phytoplasma subcluster. Strain disparities revealed by HMA and sequence data were mostly in agreement, highlighting the utility of HMA in differentiation and classification of phytoplasmas belonging to the same ribosomal RNA group.     

Pear decline in Spain

Pear decline in Spain, associated with the presence of phytoplasmas in sieve tubes, was studied. Samples of healthy and diseased pear trees were tested to confirm the presence of the pathogen. The polymerase chain reaction (PCR) technique was used, with universal and specific primers. Specimens of Cacopsylla pyri were also analysed by PCR. Phytoplasmas were detected in 79% of trees with premature reddening, in 67% of trees with weakness and necrotic spots (cv. Limonera) and in 20% of trees without symptoms. The pathogen was also detected in the psyllids, indicating that C. pyri could be the vector of the disease in Spain.     

European stone fruit yellows phytoplasmas associated with a decline disease of apricot in southern England

Phytoplasmas detected by fluorescence microscopy and polymerase chain reaction (PCR) have been discovered infecting Prunus trees at a site in south-east England. The pathogens were detected in tissue samples taken in autumn and also in spring. The symptoms in infected trees varied from severe decline to absence. PCR experiments using group-specific primers to amplify regions of the 16S RNA gene indicated that the phytoplasmas are similar to European stone fruit yellows isolates occurring in southern and eastern Europe. This is the first record of phytoplasmas in Prunus species in the UK. The origin of the infection is unknown. The implications of this new disease for the fruit industry are discussed.     

Differential detection and genetic relatedness of phytoplasmas in papaya

The genetic relatedness of phytoplasmas associated with dieback (PDB), yellow crinkle (PYC) and mosaic (PM) diseases in papaya was studied by restriction fragment length polymorphism (RFLP) analysis of the 16S rRNA gene and 16S rRNA/23S rRNA spacer region (SR). RFLP and SR sequence comparisons indicated that PYC and PM phytoplasmas were identical and most closely related to members of the faba bean phyllody strain cluster. By comparison the PDB phytoplasma was most closely related to Phormium yellow leaf (PYL) phytoplasma from New Zealand and the Australian grapevine yellows (AGY) phytoplasma from Australia. These three phytoplasmas cluster with the stolbur and German grapevine yellows (VK) phytoplasmas within the aster yellows strain cluster. Primers based on the phytoplasma tuf gene, which amplify gene products from members of the AY strain cluster, also amplified a DNA product from the PDB phytoplasma but not from either the PYC or PM phytoplasmas. Primers deduced from the 16S rRNA/SR selectively amplified rDNA sequences from the PDB and AGY phytoplasmas but not from other members of the stolbur strain cluster. Similarly, primers designed from 16S rRNA/SR amplified rDNA from the PYC and PM phytoplasmas but not from the PDB phytoplasma. These primers may provide for more specific detection of these pathogens in epidemiological studies.     

Molecular identification of a new phytoplasma associated with alfalfa witches'-broom in oman

ABSTRACT Alfalfa (Medicago sativa) plants showing witches'-broom symptoms typical of phytoplasmas were observed from Al-Batinah, Al-Sharqiya, Al-Bureimi, and interior regions of the Sultanate of Oman. Phytoplasmas were detected from all symptomatic samples by the specific amplification of their 16S-23S rRNA gene. Polymerase chain reaction (PCR), utilizing phytoplasma-specific universal primer pairs, consistently amplified a product of expected lengths when DNA extract from symptomatic samples was used as template. Asymptomatic plant samples and the negative control yielded no amplification. Restriction fragment length polymorphism profiles of PCR-amplified 16S-23S rDNA of alfalfa using the P1/P7 primer pair identified phytoplasmas belonging to peanut witches'-broom group (16SrII or faba bean phyllody). Restriction enzyme profiles showed that the phytoplasmas detected in all 300 samples belonged to the same ribosomal group. Extensive comparative analyses on P1/P7 amplimers of 20 phytoplasmas with Tru9I, Tsp509I, HpaII, TaqI, and RsaI clearly indicated that this phytoplasma is different from all the other phytoplasmas employed belonging to subgroup 16SrII, except tomato big bud phytoplasma from Australia, and could be therefore classified in subgroup 16SrII-D. The alfalfa witches'-broom (AlfWB) phytoplasma P1/P7 PCR product was sequenced directly after cloning and yielded a 1,690-bp product. The homology search showed 99% similarity (1,667 of 1,690 base identity) with papaya yellow crinkle (PapayaYC) phytoplasma from New Zealand. A phylogenetic tree based on 16S plus spacer regions sequences of 35 phytoplasmas, mainly from the Southern Hemisphere, showed that AlfWB is a new phytoplasma species, with closest relationships to PapayaYC phytoplasmas from New Zealand and Chinese pigeon pea witches'-broom phytoplasmas from Taiwan but distinguishable from them considering the different associated plant hosts and the extreme geographical isolation.     

Phytoplasmas associated with disease of coconut in Malaysia: phylogenetic groups and host plant species

Coconut palm ( Cocos nucifera ), oil palm ( Elaeis guineensis ), Bermudagrass ( Cynodon dactylon ) and Madagascar periwinkle ( Catharanthus roseus ) with symptoms indicative of phytoplasma disease were collected from different locations in Malaysia. PCR assays employing phytoplasma universal rRNA gene primers P1/P7 alone or P1/P7 followed by R16F2n/R16R2 detected phytoplasmas in eight out of 20 Malayan Red Dwarf (MRD), nine out of 12 Malayan Yellow Dwarf (MYD) and 12 out of 12 Malayan Tall (MT) coconut palms displaying coconut yellow decline symptoms. Positive detections were also obtained from six out of six oil palm seedlings showing symptoms of yellowing and necrosis, from 10 out of 10 Bermudagrass samples with white leaf symptoms, and from eight out of eight periwinkle plants showing phyllody, virescence, little leaf, proliferation and foliar yellowing. Phytoplasmas were not detected in any of the symptomless plants tested. Sequencing and phylogenetic analysis of PCR products determined that phytoplasmas infecting both MRD and MT coconuts and Bermudagrass in Serdang, Selangor State, were all members of the 16SrXIV ' Candidatus Phytoplasma cynodontis' group, whereas isolates in periwinkle in Serdang were all members of the 16SrI ' Ca. Phytoplasma asteris' group. However, the phytoplasmas detected in MYD coconuts and oil palms from Banting, Selangor State, and in periwinkle from Putrajaya were collectively very similar (99%), but shared <97·5% similarity with 16S rDNA sequences of all other known phytoplasmas, indicating that they represent a novel taxonomic group. Thus, at least two phylogenetically distinct phytoplasmas are associated with the coconut yellow decline syndrome in Malaysia, both of which were also detected in other plant species.     

Real-time PCR detection systems for Flavescence dorée and Bois noir phytoplasmas in grapevine: comparison with conventional PCR detection and application in diagnostics

A new real-time PCR detection system was developed for grapevine yellows (GY) using TaqMan minor groove binder probes and including two amplicons for group-specific detection of Flavescence dorée (FD) and Bois noir (BN) phytoplasmas, plus a universal phytoplasma amplicon. FD and BN amplicons were designed to amplify species-specific genomic DNA fragments and the universal amplicon to amplify the 16S ribosomal DNA region. Efficiency of PCR amplification, limit of detection, range of linearity and dynamic range were assessed for all three amplicons. The specificity of detection systems was tested on several other isolates of phytoplasmas and bacteria and on healthy field grapevine and insect samples. No cross-reactivity with other phytoplasma strains, plant or insect DNA was detected. The assay was compared with conventional PCR on more than 150 field grapevine, insect and field bindweed samples. Real-time PCR showed higher sensitivity as phytoplasmas were detected in several PCR-negative and in all PCR-positive samples. A data-mining analysis of results from both detection approaches also favoured real-time PCR over conventional PCR diagnostics. The developed procedure for detection of phytoplasmas in grapevine also included amplification of plant DNA co-extracted with phytoplasmic DNA, providing additional quality control for the DNA extraction and PCR amplification for each sample. The newly developed assay is a reliable, specific and sensitive method easily applicable to high-throughput diagnosis of GY.     

Partial characterization of phytoplasmas associated with lettuce and wild lettuce phyllodies in Iran

Phytoplasmas associated with lettuce phyllody (LP) and wild lettuce phyllody (WLP) in southern Iran were partially characterized by molecular analyses and host-range studies. Agents of both diseases were transmitted by Neoaliturus fenestratus , a leafhopper colonizing lettuce and wild lettuce, to lettuce, wild lettuce, sowthistle and periwinkle, but not to safflower, sunflower, calendula and sesame. Both phytoplasmas induced bud proliferation, virescence, phyllody and witches' broom in infected plants. Total DNA extracted from infected lettuce and wild lettuce or from vector tissues was subjected to PCR using phytoplasma-specific primer pair P1/P7 or nested PCR using P1/P7 followed by R16F2n/R16R2. PCR product of nested PCR (1·2 kbp) was subjected to restriction fragment length polymorphism (RFLP). RFLP analysis of nested PCR product identified the LP, WLP and N. fenestratus -associated phytoplasmas as members of the pigeon pea witches' broom group, 16SrIX. Phylogenetic analysis of the 16S rRNA gene sequence also clustered LP and WLP phytoplasmas with other known members of the 16SrIX group. While no significant differences could be detected between LP and WLP phytoplasmas, both isolates differed from Lebanese wild lettuce phyllody in molecular properties.     

Phloem and xylem modifications of Vitis vinifera stems in response to flavescence dorée phytoplasma infection

Anatomical modifications of xylem and phloem tissues of grapevine (Vitis vinifera) stems of shoots infected by the flavescence dorée phytoplasma (FDp) were first observed and described in the 1960s, but never quantified in detail. In this paper, we describe and quantify the impact of FDp on grapevine stem tissues, and relate it to the level of expression of symptoms and to cultivar-specific FDp susceptibility. For this purpose, we measured and quantified the anatomical parameters of xylem and phloem tissues of a tolerant (Merlot) and a susceptible (Chardonnay) cultivar. For each cultivar, thin sections of eight shoots with symptoms from FDp-infected grapevines, eight symptomless shoots from the same FDp-infected grapevines, and eight symptomless shoots from symptomless grapevines (control) were compared. Results showed general inhibition of xylem growth and proliferation of phloem tissues (hyperplasia) with lack or irregular arrangement of the fibre-sclereids in the axial phloem of the stems from shoots with symptoms, irrespective of the cultivar. Xylem vessels of infected Merlot shoots were partly occluded by tyloses and a higher number of smaller vessels were produced than in control plants. Thus, the anatomical responses confirmed the detrimental effect of FDp on stems of infected grapevine shoots, including impaired stem development and lack of periderm formation. Statistically significant differences were found between the two cultivars with different levels of susceptibility to FDp infection.     

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.     

Identification of Mulberry Dwarf Phytoplasmas in the Genital Organs and Eggs of Leafhopper Hishimonoides sellatiformis

ABSTRACT The presence of mulberry dwarf (MD) phytoplasmas in organs of the inoculative vector insects Hishimonoides sellatiformis and Hishimonus sellatus was determined by means of electron microscopy (EM) and polymerase chain reaction (PCR) assays. Many MD phytoplasmas were detected in genital organs as well as in the intestines, salivary glands, brains, fat bodies, and thoracic ganglia of Hishimonoides sellatiformis, but only in the intestine and salivary glands of Hishimonus sellatus. Many phytoplasmas with characteristic morphology were observed via EM in ovaries, seminal receptacles, and testes, and they were further identified by PCR assays with group I-specific primers. In addition, the organisms were detected by direct or nested PCR assays in eggs (head pigmentation stage of embryos) laid on mulberry shoots by inoculative leafhoppers and in the newly hatched nymphs from these eggs. These findings indicate that transovarial transmission of MD phytoplasmas occurs in Hishimonoides sellatiformis.     

Long-term maintenance of nonculturable apple-proliferation phytoplasmas in their micropropagated natural host plant

Phytoplasmas associated with apple proliferation (AP) disease of apple trees have been maintained in their micropropagated natural host plant Malus pumila since 1985. Different isolates of these nonculturable plant pathogens could thus be studied in vitro . Amplification of a pathogen-specific DNA fragment by polymerase chain reaction (PCR) confirmed the presence of AP phytoplasmas in the diseased plants even after 10 years of in-vitro propagation. Restriction fragment length polymorphism analysis of the amplified chromosomal DNA fragments revealed no genetic difference between the AP phytoplasma isolates. Growth parameters, symptom expression and phytoplasma concentration were examined to compare the in-vitro behaviour of four different AP phytoplasma isolates and to compare different subculture conditions. A comparison of these data obtained after 2 or 8 years of micropropagation revealed no essential differences. Eight years after culture initiation, diseased shoots still exhibited typical symptoms like witches' broom, small leaves with large stipules and stunted growth. The use of phytoplasma-diseased micropropagated plants to establish a 'type culture collection' of these otherwise nonculturable plant pathogens is discussed.     

Mapping the spread of apricot chlorotic leaf roll (ACLR) in southern France and implication of Cacopsylla pruni as a vector of European stone fruit yellows (ESFY) phytoplasmas

An epidemiological study on European stone fruit yellows (ESFY) phytoplasmas infecting Prunus fruit trees was carried out from 1994 to 2000 in Languedoc-Roussillon (southern France). The spread of the disease was monitored for 7 years by visual observation of symptoms and by PCR detection of the phytoplasma in an experimental orchard planted with apricot hybrid seedlings. This indicated that aerial vectors were responsible for disease spread, and that transmission rates were low at the beginning of the spread. Seventy thousand homopteran insects were captured within and in the surroundings of highly ESFY-infected apricot orchards, of which about 10 000 were used in PCR and nested-PCR assays with universal ribosomal and ESFY-specific nonribosomal primers to detect ESFY phytoplasmas. The other insects were confined in cages for trials of transmission to test plants. ESFY phytoplasmas could not be detected by PCR in any of the leafhopper species captured but could be detected in the psyllid Cacopsylla pruni caught on Prunus domestica and Prunus cerasifera rootstock suckers of apricot trees and on Prunus spinosa . Nested PCR revealed ESFY phytoplasmas in one individual of the deltocephalid Synophropsis lauri captured on an apricot tree. Transmission trials confirmed the role of Cacopsylla pruni as the ESFY phytoplasma vector in France. When apricot seedlings were used as bait plants from April to November during two consecutive years, no natural transmission could be demonstrated. However, one out of 50 apricot seedlings left for the whole year in the orchard became infected. An early spring ESFY infection is in agreement with both the natural transmission results and the life cycle of Cacopsylla pruni .     

Isolation of Peirce's disease bacteria from grapevines in Europe

Xylella fastidiosa, the causal agent of Pierce's disease (PD) of grape, was isolated from diseased grapevines grown in Kosova, Yugoslavia. The Kosova isolate was a rod-shaped bacterium which showed a typically rippled cell wall under electron microscopy. ELISA comparisons indicated that the Kosova isolate was closely related to the U.S. PD strains and to several other strains of X. fastidiosa. When DNA extracted from diseased grapevines collected from Kosova was used as template in PCR with primer sets specific for X. fastidiosa, a band of about 730 bp diagnostic for PD bacteria was detected. DNA from the isolated Kosova bacteria and the type strain of PD yielded the same length of DNA fragment in PCR assay. The Kosova isolate was inoculated into young healthy grapevines through the roots with negative pressure applied to the shoots. Typical scald and scorch symptoms appeared on the leaves of the inoculated grapevines 40–80 days after inoculation. The same bacteria were reisolated from these inoculated diseased plants and used to reinoculate young grapevines. The reinoculated grapevines produced the same symptoms, thereby fulfilling Koch's postulates. This is the first confirmation that PD of grapes occurs in Europe.     

Detection and identification of a phytoplasma from lucerne with Australian lucerne yellows disease

Foliar and root symptoms are described for Australian lucerne yellows (ALuY), a disease common in Australian lucerne seed crops. A phytoplasma was detected in plants exhibiting symptoms, but not in symptomless lucerne plants. Oligonucleotide primers specific to the phytoplasma 16S-23S rRNA intergenic spacer region (SR) were used in polymerase chain reaction (PCR) assays on DNA extracted from lucerne plants with and without symptoms. Identical restriction fragment length polymorphism (RFLP) enzyme profiles were obtained for PCR products amplified from 10 yellows-affected lucerne samples. RFLP profiles obtained for four restriction enzymes were different from those of the tomato big bud (TBB) phytoplasma. ALuY phytoplasma PCR products were sequenced to determine phylogeny and were found to fall within the faba bean phyllody phytoplasma group, or phytoplasma group 16srII. Transmission electron microscopy revealed phytoplasmas in the phloem of yellows-affected plant samples, but not in symptomless plant samples. Fungal, bacterial and viral agents in the aetiology of Australian lucerne yellows were ruled out.     

Grapevine virus A variants of group II associated with Shiraz disease in South Africa are present in plants affected by Australian Shiraz disease,and have also been detected in the USA

Primers were designed for RT‐nested PCR amplification of the highly variable 293‐nt fragment from the 5′ terminal part of the Grapevine virus A (GVA) replicase gene, specific to South African variants of molecular groups I and II. This new technique, along with RT‐PCR for simultaneous amplification of variants of groups I, II and III, as well as cloning of amplicons, single‐strand conformation polymorphism (SSCP) analysis of clones and sequencing, were used to investigate the populations of variants infecting 16 local Shiraz grapevines with different Shiraz disease (SD) status. The techniques were also used to study variants in GVA‐infected grapevines from Australia and the USA. The Australian grapevines included seven plants of cvs Shiraz and Merlot affected by Australian Shiraz disease (AuSD), and one plant of cv. Crimson Seedless with unknown AuSD status. Grapevines from the USA included plants of cvs Chardonnay, Thompson Seedless and an unknown cultivar. The results confirmed the association of certain genetic variants of group II with SD and showed the common presence of these variants in AuSD‐affected grapevines from Australia. Interestingly, a variant of this group was also detected in grapevine cv. Chardonnay from the USA, although the disease has not yet been reported from that country. The study also supports an earlier observation that members of group II, closely related to variant GTR1‐2, are not associated with the disease. The variants were found only in SD‐free grapevines. Results show that variants of the most divergent group III, which are common in South Africa, are also present in Australia and the USA. These variants are not associated with SD, but frequently occur in mixed infections with members of group II in plants affected by this disease in South Africa.     

从吐鲁番古葡萄树上检测到4种类病毒(AGVd、GYSVd-1、GYSVd-2、HSVd)

从约有150年树龄的新疆吐鲁番葡萄(品种无核白)叶子中抽提小分子RNA,经过RT-PCR、生物学检测及克隆测序分析,证明其中含有4种类病毒:AGVd、GYSVd-1、GYSVd-2和HSVd。通过二维电泳,正反向电泳及Northern印迹杂交,RT-PCR等分子生物学方法对接种的指示植物Suyo黄瓜中的子代类病毒进行了检测,结果仅仅检测到HSVd一种类病毒。对Suyo黄瓜中的HSVd子代类病毒进行克隆及序列分析,结果表明葡萄中亲代类病毒与黄瓜中的子代类病毒序列之间存在明显差异。     

Detection of lethal yellowing phytoplasma in embryos from coconut palms infected with Cape St Paul wilt disease in Ghana

This study investigated the potential of seed transmission of Cape St. Paul wilt disease (CSPWD) in coconuts. PCR amplification was used to assess the distribution of phytoplasmas in parts of West African Tall (WAT) palms infected with CSPWD. Employing phytoplasma universal primer pair P1/P7 in standard PCR, or followed with a nested PCR using CSPWD–specific primer pair G813f/AwkaSR, phytoplasma infection was detected in the trunks, peduncles, spikelets, male and female flowers of four infected WAT coconut palms. Through nested PCR, phytoplasma was also detected in four of 19 embryo DNA samples extracted individually from fruits harvested from three of the four infected palms and was confirmed as CSPWD by cloning and sequencing. Subsequently, CSPWD phytoplasma was again detected in five of 33 embryos from nine infected palms, and in one of eight fruits from two symptomless palms. Fruits from infected palms recorded higher percentage germinations in two field nurseries (average of 71·0%) compared to fruits from healthy palms (average of 57·6%), and matured fruits that had dropped from infected palms showed the same levels of germination as those harvested directly from the palms. This indicates that infected fruits retain the ability to germinate whether harvested or dropped. No phytoplasmas were detected in any of the resulting seedlings and plantlets obtained through embryo in-vitro culture. Therefore, although phytoplasma DNA can be detected in embryos, there is as yet no evidence that the pathogen is seed transmitted through to the seedling to cause disease in progeny palms.     

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.     

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.