First Report of Aster Yellows Phytoplasma (16SrI‐B) Associated with Witches' Broom Disease of Melia azedarach var. japonica in Korea

Melia azedarach var. japonica trees with leaf yellowing, small leaves and witches' broom were observed for the first time in Korea. A phytoplasma from the symptomatic leaves was identified based on the 16Sr DNA sequence as a member of aster yellows group, ribosomal subgroup 16SrI‐B. Sequence analyses of more variable regions such as 16S–23S intergenic spacer region, secY gene, ribosomal protein (rp) operon and tuf gene showed 99.5?100% nucleotide identity to several GenBank sequences of group 16SrI phytoplasmas. Phylogenetic analysis confirmed that the Melia azedarach witches' broom phytoplasma belongs to aster yellows group.     

Detection and Identification of Aster Yellows (16SrI) Phytoplasma in Peach Trees in Jordan by RFLP Analysis of PCR-Amplified Products (16S rDNAs)

Aster yellows phytoplasma were detected, for the first time, in peach trees in Al‐Jubiha and Homret Al‐Sahen area. Leaves of infected trees showed yellow or reddish, irregular water‐soaked blotches. Discoloured areas become dry and brittle and the dead tissues dropped out. Under severe infections, leaves fall down and fruits dropped prematurely. Phytoplasmas were detected from all symptomatic peach trees by polymerase chain reaction (PCR) using universal phytoplasmas primers P1/P7 followed by R16F2/R2. No amplification products were obtained from templates of asymptomatic peaches. PCR products (1.2 kb) used for restriction fragment length polymorphism analysis (RFLP) after digestion with endonuclease AluI, HpaII, KpnI and RsaI produced the same restriction profiles for all samples, and they were identical with those of American aster yellows (16SrI) phytoplasma strain. This paper is the first report on aster yellows phytoplasma affecting peach trees in Jordan.     

Molecular Characterization of Aster Yellows Subgroup 16SrI‐B Phytoplasma in Verbena × hybrida

Symptoms resembling phytoplasma disease were observed on Verbena × hybrida in Alanya, Turkey, during October 2013. Infected plants were growing as perennials in a flower border and showed symptoms of discoloured flowers, poor flower clusters, inflorescences with a small number of developed flowers and thickened fruit stalks. Electron microscopy examination of the ultra‐thin sections revealed polymorphic bodies in the phloem tissue of leaf midribs. The phytoplasma aetiology of this disease was confirmed by polymerase chain reaction of the 16S rRNA gene, the 16–23S rRNA intergenic spacer region and the start of the 23S rRNA gene using universal phytoplasma‐specific primer pair P1A/P7A, two ribosomal protein (rp) genes (rpl22 and rps3) (the group‐specific primer pair rp(I)F1A/rp(I)R1A) and the Tuf gene (group‐specific fTufAy/rTufAy primers) generating amplicons of 1.8 kbp, 1.2 kbp and 940 bp, respectively. Comparison of the amplified sequences with those available in GenBank allowed classification of the phytoplasma into aster yellows subgroups 16SrI‐B, rpI‐B and tufI‐B. This is the first report about molecular detection and identification of natural infection of the genus Verbena by phytoplasma and occurrence of the aster yellows group phytoplasma on an ornamental plant in Turkey.     

The phytoplasma associated with purple woodnettle witches'‐broom disease in Taiwan represents a new subgroup of the aster yellows phytoplasma group

In October 2013, a new disease affecting purple woodnettle, Oreocnide pedunculata, plants was found in Miaoli County, Taiwan. Diseased plants exhibited leaf yellowing and witches'‐broom symptoms. Molecular diagnostic tools and electron microscopic cell observation were used to investigate the possible cause of the disease with a specific focus on phytoplasmas. The result of polymerase chain reaction with universal primer pairs indicated that phytoplasmas were strongly associated with the symptomatic purple woodnettles. The virtual restriction fragment length polymorphism (RFLP) patterns and phylogenetic analysis based on 16S rDNA and ribosomal protein, rplV‐rpsC region revealed that purple woodnettle witches'‐broom phytoplasma (PWWB) belongs to a new subgroup of 16SrI and rpI group and was designated as 16SrI‐AH and rpI‐Q, respectively, herein. RFLP analysis based on tuf gene region revealed that the PWWB belongs to tufI‐B, but phylogenetic analysis suggested that PWWB should be delineated to a new subgroup under the tufI group. Taken together, our analyses based on 16S rRNA and rplV‐rpsC region gave a finer differentiation while classifying the subgroup of aster yellows group phytoplasmas. To our knowledge, this is the first report of a Candidatus Phytoplasma asteris‐related strain in 16SrI‐AH, rpI‐Q and tufI‐B subgroup affecting purple woodnettle, and of an official documentation of purple woodnettle as being a new host of phytoplasmas.     

Multigene Sequence Analysis of Aster Yellows Phytoplasma Associated with Primrose Yellows

Primula acaulis (L.) Hill. plants showing stunting, leaf‐yellowing and virescence were first discovered in the Czech Republic. Polymerase chain reactions with subsequent restriction fragment length polymorphism analyses and sequencing enabled classification of the detected phytoplasmas into the aster yellows group, ribosomal subgroup 16SrI‐B, tufI‐B, rpI‐B, groELIB‐III and SecY‐IB subgroups. Phylogeny of the 16S rRNA gene sequences as well as sequence analysis of several chromosomal regions, such as the 16S‐23S ribosomal operon, ribosomal proteins, spc ribosomal protein operon, genes for elongation factor EF‐Tu, molecular chaperonin large subunit GroEL, immunodominant membrane protein, ribosome recycling factor, urydilate kinase, ATP‐ and Zn²⁺‐dependent proteases not only confirmed its affiliation with the ‘Candidatus Phytoplasma asteris’ species but also enabled its detailed molecular characterization. The less researched regions of phytoplasma genome (amp, adk, hflB, pyrH‐frr genes) could be valuable as additional markers for phytoplasma through differentiation especially within the 16SrI‐B ribosomal subgroup.     

Detection and Identification of Aster Yellows Phytoplasma Associated with Lipstick Yellow Frond Disease in Malaysia

Yellowing symptoms similar to coconut yellow decline phytoplasma disease were observed on lipstick palms (Cyrtostachys renda) in Selangor state, Malaysia. Typical symptoms were yellowing, light green fronds, gradual collapse of older fronds and decline in growth. Polymerase chain reaction assay was employed to detect phytoplasma in symptomatic lipstick palms. Extracted DNA was amplified from symptomatic lipstick palms by PCR using phytoplasma‐universal primer pair P1/P7 followed by R16F2n/R16R2. Phytoplasma presence was confirmed, and the 1250 bp products were cloned and sequenced. Sequence analysis indicated that the phytoplasmas associated with lipstick yellow frond disease were isolates of ‘Candidatus Phytoplasma asteris’ belonging to the 16SrI group. Virtual RFLP analysis of the resulting profiles revealed that these palm‐infecting phytoplasmas belong to subgroup 16SrI‐B and a possibly new 16SrI‐subgroup. This is the first report of lipstick palm as a new host of aster yellows phytoplasma (16SrI) in Malaysia and worldwide.     

‘Candidatus Phytoplasma asteris’ and ‘Candidatus Phytoplasma aurantifolia’, New Phytoplasma Species Infecting Apple Trees in Iran

During several surveys in extensive areas in central Iran, apple trees showing phytoplasma diseases symptoms were observed. PCR tests using phytoplasma universal primer pairs P1A/P7A followed by R16F2n/R16R2 confirmed the association of phytoplasmas with symptomatic apple trees. Nested PCR using 16SrX group‐specific primer pair R16(X)F1/R1 and aster yellows group‐specific primer pairs rp(I)F1A/rp(I)R1A and fTufAy/rTufAy indicated that apple phytoplasmas in these regions did not belong to the apple proliferation group, whereas aster yellows group‐related phytoplasmas caused disease on some trees. Restriction fragment length polymorphism (RFLP) analyses using four restriction enzymes (HhaI, HpaII, HaeIII and RsaI) and sequence analyses of partial 16S rRNA and rp genes demonstrated that apple phytoplasma isolates in the centre of Iran are related to ‘Ca. Phytoplasma asteris’ and ‘Ca. Phytoplasma aurantifolia’. This is the first report of apples infected with ‘Ca. Phytoplasma asteris’ in Iran and the first record from association of ‘Ca. Phytoplasma aurantifolia’ with apples worldwide.     

First Report of Phytoplasma (16SrI) Associated with Yellow Decline Disease of Royal Palms [Roystonea regia (Kunth) O. F. Cook] in Malaysia

Royal Palms (Roystonea regia) with symptoms such as severe chlorosis, stunting, collapse of older fronds and general decline were observed in the state of Selangor, Malaysia. Using polymerase chain reaction (PCR) amplification with phytoplasma universal primer pair P1/P7 followed by R16F2N/R16R2 and fU5/rU3 as nested PCR primer pairs, all symptomatic plants tested positively for phytoplasma. Results of phylogenetic and virtual RFLP analysis of the 16S rRNA gene sequences revealed that the phytoplasma associated with Royal Palm yellow decline (RYD) was an isolate of ‘Candidatus Phytoplasma asteris’ belonging to a new 16SrI‐subgroup. These results show that Roystonea regia is a new host for the aster yellows phytoplasma (16SrI). This is the first report on the presence of 16SrI phytoplasma on Royal Palm trees in Malaysia.     

Characterisation and phylogeny of a phytoplasma inducing sandal spike disease in sandal (Santalum album)

Sandal (Santalum album) is an industrially important forest species in India, where it is devastated by sandal spike (SAS) disease. Diseased S. album trees show characteristic witches’ broom symptoms suspected to be caused by phytoplasma. Since the first report of occurrence of this disease at the end of 19th century, studies mainly have been carried out to detect SAS phytoplasma through various approaches. The causative agent, however, has remained poorly characterised at a molecular level. The present investigation was aimed to characterise the pathogen at this level. In nested PCR, a 1.4‐kb 16S rDNA fragment was amplified and analysed by restriction fragment length polymorphism using 17 restriction enzymes. The patterns were identical to those of strains AY1 and APh of the aster yellows subgroup 16SrI‐B, except for BfaI, which gave a different pattern. After cloning and sequencing, a phylogenetic analysis revealed the closest relationship to aster yellows subgroup 16SrI‐B members. Nucleotide sequence identity ranged from 99.2% to 99.5% with this subgroup. On the basis of these results, the SAS phytoplasma was classified as a member of subgroup 16SrI‐B.     

Detection and Characterization of Phytoplasmas Infecting Ornamental and Weed Plants in Iran

During field surveys in 2004, ornamental and weed plants showing symptoms resembling those caused by phytoplasmas were observed in Mahallat (central Iran). These plants were examined for phytoplasma infections by polymerase chain reaction (PCR) assays using universal phytoplasma primers directed to ribosomal DNA (rDNA). All affected plants gave positive results. The detected phytoplasmas were characterized and differentiated through restriction fragment length polymorphism (RFLP) and sequence analysis of PCR‐amplified rDNA. The phytoplasmas detected in diseased Asclepias curassavica and Celosia argentea were identified as members of clover proliferation phytoplasma group (16SrVI group) whereas those from the remaining plants examined proved to be members of aster yellow phytoplasma group (16SrI group) (‘Candidatus Phytoplasma asteris’). In particular, following digestion with AluI, HaeIII and HhaI endonucleases, the phytoplasma detected in Limonium sinuatum showed restriction profiles identical to subgroup 16SrI‐C; phytoplasmas from Gomphocarpus physocarpus, Tanatacetum partenium, Lactuca serriola, Tagetes patula and Coreopsis lanceolata had the same restriction profiles as subgroup 16SrI‐B whereas Catharanthus roseus‐ and Rudbeckia hirta‐infecting phytoplasmas showed restriction patterns of subgroup 16SrI‐A. This is the first report on the occurrence of phytoplasma diseases of ornamental plants in Iran.     

Asparagus officinalis: A New Host of ‘Candidatus Phytoplasma asteris’

Asparagus officinalis plants with severe fasciation of some spears were observed in southern Bohemia between 1998 and 2007. Nucleic acids extracted from these and asymptomatic plants were assayed with nested polymerase chain reaction (PCR) using the phytoplasma‐specific universal ribosomal primers P1/P7 and R16F2n/R2. The restriction profiles obtained from digestion of the PCR products with five endonucleases (AluI, HhaI, KpnI, MseI and RsaI) were identical in all phytoplasmas infecting asparagus in the Czech Republic and indistinguishable from those of phytoplasmas in the aster yellows group (subgroup 16SrI‐B). Sequence analysis of 1754 bp of the ribosomal operon indicated that the closest related phytoplasmas were those associated with epilobium phyllody and onion yellows. This is the first report of the natural occurrence of ‘Candidatus Phytoplasma asteris’ in A. officinalis.     

泡桐丛枝和枣疯病植原体tuf基因上游序列结构、功能和遗传变异比较分析

【目的】探究泡桐丛枝和枣疯病植原体tuf基因上游序列结构、功能差异及其遗传多样性。【方法】利用热不对称交错式PCR(TAIL-PCR)扩增枣疯病植原体tuf基因上游未知序列,利用启动子探针载体pSUPV4构建了泡桐丛枝和枣疯病植原体tuf基因上游序列的大肠杆菌异源表达体系,分析泡桐丛枝、苦楝丛枝、莴苣黄化、桑萎缩、长春花绿变等16SrI组和枣疯病、樱桃致死黄化、重阳木丛枝等16SrV组株系tuf基因上游调控序列的遗传变异特征和启动子活性。【结果】泡桐丛枝等16SrI组植原体株系tuf基因和其上游fus A基因之间的间区序列长129-130 bp,预测有完整的启动子保守结构。泡桐丛枝植原体tuf基因上游130 bp片段具有启动子活性,此间区序列在5种35株16SrI组株系中存在4种变异类型;枣疯病植原体等16SrV组株系fusA和tuf基因间区长53-54 bp,未预测到完整启动子结构。枣疯病植原体tuf基因上游144 bp和346 bp片段均未检测到启动子活性,fus A和tuf基因间区序列在3种20株16SrV组株系中存在2种变异类型。fus A-tuf基因间区序列相对保守,基于此序列构建的进化树可清晰区分不同组别的植原体株系。【结论】研究方法和结果为深入研究植原体基因表达与调控、揭示植原体生长繁殖规律及其致病机理等奠定了良好的基础。     

Detection and Characterization of Phytoplasma and Sugarcane Yellow Leaf Virus Associated with Leaf Yellowing of Sugarcane

Leaves from sugarcane were collected from Egyptian plantation fields and tested for phytoplasma (Sugarcane yellows phytoplasma, SCYP) and Sugarcane yellow leaf virus (SCYLV) using nested PCR (with different primers) and RT‐PCR, respectively. These results showed significant differences in the amplification of the PCR assays. The primer MLO‐X/MLO‐Y, which amplified the 16S‐23S rDNA spacer region, was the most precise to detect the phytoplasma in sugarcane plants. Sequencing and restriction fragment length polymorphism analysis revealed that all tested phytoplasmas belonged to the 16SrI (aster yellows phytoplasma) group, with the exception of cultivar G84‐47 belonged to the 16SrXI (Rice yellow dwarf phytoplasma) group. Three Egyptian sugarcane cultivars were phytoplasma free. Phylogenetic analyses of 34 screened accessions of 16S ribosomal DNA gene sequences of Candidatus phytoplasma including the ones collected from Egypt used in this study and those extracted from GenBank showed that they split into two distinct clusters. The phylogenetic analyses indicated that these phytoplasmas are closely related and share a common ancestor. All tested Egyptian sugarcane plants were infected by SCYLV with the exception of cultivar Phil‐8013 which was virus free.     

Molecular Identification and Phylogenetic Analysis of Sugarcane Yellow Leaf Phytoplasma (SCYLP) in Egypt

Samples of sugarcane leaves were collected from different commercial fields and breeding stations in Egypt. Aetiology of sugarcane phytoplasma disease was investigated using nested PCR. Phytoplasma‐specific primers (P1/P7 and R16F2n/R16R2) were used to amplify a fragment of the 16S rRNA gene. Sequencing and restriction fragment length polymorphism analyses revealed that the tested phytoplasmas belonged to the 16SrI (aster yellows phytoplasma) group. Phylogenetic analyses of 60 screened accessions of 16S ribosomal RNA gene sequences of Candidatus phytoplasmas comprising those collected from Egypt (this study) and those extracted from GenBank showed that they split into two distinct clusters. All the phytoplasmas form a stable phylogenetic subcluster, as judged by branch length and bootstrap values of 100% in the 16S group cluster. Results of phylogenetic analyses indicated that these phytoplasmas are closely related and share a common ancestor. Conversely, based on the analysis of the 16S‐23S region, examined isolates segregated into four different clusters suggesting a notable heterogeneity between them. These results are the first record of the presence of phytoplasma in association with sugarcane yellow leaf in Egypt.     

Identification of Phytoplasmas Associated with Grapevine Yellows in Serbia

The molecular identification and characterization of phytoplasmas from infected grapevines in four locations in Serbia are reported. Phytoplasmas were detected and identified by restriction fragment length polymorphism (RFLP) analysis of polymerase chain reaction (PCR) amplified 16S rDNA. Grapevine yellows were associated with three molecularly distinguishable phytoplasmas: Flavescence dorée phytoplasmas (elm yellows group: 16SrV‐C subgroup) were present only in the Župa Aleksandrovac region; Bois noir phytoplasmas (stolbur group: 16SrXII‐A subgroup) were detected in the other surveyed regions; a mixed infection of European stone fruit yellows (apple proliferation group: 16SrX‐B subgroup) and Bois noir phytoplasmas was identified in one sample. A finer molecular characterization by RFLP analysis of rpS3 and SecY genes of Flavescence dorée phytoplasmas from Župa Aleksandrovac confirmed that the Serbian genotype is indistinguishable from a strain from the Veneto region, Italy. Characterization of the tuf gene of Bois noir phytoplasmas showed lack of amplification of samples from Erdevik. HpaII profiles of tuf gene PCR products of samples from Pali and Radmilovac were identical, and were indistinguishable from one of the two profiles produced by samples from Italian grapevines used as reference strains.     

Universal and group-specific real-time PCR diagnosis of flavescence dorée (16Sr-V), bois noir (16Sr-XII) and apple proliferation (16Sr-X) phytoplasmas from field-collected plant hosts and insect vectors

Three real‐time PCR–based assays for the specific diagnosis of flavescence dorée (FD), bois noir (BN) and apple proliferation (AP) phytoplasmas and a universal one for the detection of phytoplasmas belonging to groups 16Sr‐V, 16Sr‐X and 16Sr‐XII have been developed. Ribosomal‐based primers CYS2Fw/Rv and TaqMan probe CYS2 were used for universal diagnosis in real‐time PCR. For group‐specific detection of FD phytoplasma, ribosomal‐based primers fAY/rEY, specific for 16Sr‐V phytoplasmas, were chosen. For diagnosis of BN and AP phytoplasmas, specific primers were designed on non‐ribosomal and nitroreductase DNA sequences, respectively. SYBR^® Green I detection coupled with melting curve analysis was used in each group‐specific protocol. Field‐collected grapevines infected with FD and BN phytoplasmas and apple trees infected with AP phytoplasma, together with Scaphoideus titanus, Hyalesthes obsoletus and Cacopsylla melanoneura adults, captured in the same vineyards and orchards, were used as templates in real‐time PCR assays. The diagnostic efficiency of each group‐specific protocol was compared with well‐established detection procedures, based on conventional nested PCR. Universal amplification was obtained in real‐time PCR from DNAs of European aster yellows (16Sr‐I), elm yellows (16Sr‐V), stolbur (16Sr‐XII) and AP phytoplasma reference isolates maintained in periwinkles. The same assay detected phytoplasma DNA in all test plants and test insect vectors infected with FD, BN and AP phytoplasmas. Our group‐specific assays detected FD, BN, and AP phytoplasmas with high efficiencies, similar to those obtained with nested PCR and did not amplify phytoplasma DNA of other taxonomic groups. Melting curve analysis was necessary for the correct identification of the specific amplicons generated in the presence of very low target concentrations. Our work shows that real‐time PCR methods can sensitively and rapidly detect phytoplasmas at the universal or group‐specific level. This should be useful in developing defence strategies and for quantitative studies of phytoplasma–plant–vector interactions.     

The groEL gene as an additional marker for finer differentiation of ‘Candidatus Phytoplasma asteris'‐related strains

Phytoplasma classification established using 16S ribosomal groups and ‘Candidatus Phytoplasma’ taxon are mainly based on the 16S rDNA properties and do not always provide molecular distinction of the closely related strains such as those in the aster yellows group (16SrI or ‘Candidatus Phytoplasma asteris'‐related strains). Moreover, because of the highly conserved nature of the 16S rRNA gene, and of the not uncommon presence of 16S rDNA interoperon sequence heterogeneity, more variable single copy genes, such as ribosomal protein (rp), secY and tuf, were shown to be suitable for differentiation of closely related phytoplasma strains. Specific amplification of fragments containing phytoplasma groEL allowed studying its variability in 27 ‘Candidatus Phytoplasma asteris'‐related strains belonging to different 16SrI subgroups, of which 11 strains were not studied before and 8 more were not studied on other genes than 16S rDNA. The restriction fragment length polymorphism (RFLP) analyses of the amplified fragments confirmed differentiation among 16SrI‐A, I‐B, I‐C, I‐F and I‐P subgroups, and showed further differentiation in strains assigned to 16SrI‐A, 16SrI‐B and 16SrI‐C subgroups. However, analyses of groEL gene failed to discriminate strains in subgroups 16SrI‐L and 16SrI‐M (described on the basis of 16S rDNA interoperon sequence heterogeneity) from strains in subgroup 16SrI‐B. On the contrary, the 16SrI unclassified strain ca2006/5 from carrot (showing interoperon sequence heterogeneity) was differentiable on both rp and groEL genes from the strains in subgroup 16SrI‐B. These results indicate that interoperon sequence heterogeneity of strains AY2192, PRIVA (16SrI‐L), AVUT (16SrI‐M) and ca2006/5 resulted in multigenic changes – one evolutionary step further – only in the latter case. Phylogenetic analyses carried out on groEL are in agreement with 16Sr, rp and secY based phylogenies, and confirmed the differentiation obtained by RFLP analyses on groEL amplicons.     

Surveys reveal the occurrence of phytoplasmas in plants at different geographical locations in Peru

Two independent surveys were performed in Peru during February and November 2007 to detect the presence of phytoplasmas within any crops showing symptoms resembling those caused by phytoplasmas. Molecular identifications and characterisations were based on phytoplasma 16S and 23S rRNA genes using nested PCR and terminal restriction fragment length polymorphism (T‐RFLP). The surveys indicated that phytoplasmas were present in most of the locations sampled in Peru in both cultivated crops, including carrots, maize, native potatoes, improved potato, tomato, oats, papaya and coconut, and in other plants such as dandelion and the ornamental Madagascar periwinkle (Catharanthus roseus). Phylogenetic analysis of the sequences confirmed that while most of the isolates belong to the 16SrI aster yellows group, which is ubiquitous throughout other parts of South America, one isolate from potato belongs to the 16SrII peanut witches’ broom group, and one isolate from tomato and one from dandelion belong to the 16SrIII X‐disease group. The use of T‐RFLP was validated for the evaluation of phytoplasma‐affected field samples and provided no evidence for mixed infection of individual plants with more than one phytoplasma isolate. These data represent the first molecular confirmation of the presence of phytoplasmas in a broad range of crops in Peru.     

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.     

First Report of a 16SrI‐C Phytoplasma Infecting Celery (Apium graveolens) with Stunting,Bushy Top and Phyllody in the Czech Republic

Apium graveolens L. plants showing stunting, purplish/whitening of new leaves, flower abnormalities and bushy tops were observed in South Bohemia (Czech Republic) during 2011 and 2012. Transmission electron microscopy observations showed phytoplasmas in phloem sieve tube elements of symptomatic but not healthy plants. Polymerase chain reactions with universal and group‐specific phytoplasma primers followed by restriction fragment length polymorphism analyses and sequencing of 16S rDNA enabled classification of the detected phytoplasmas into the aster yellows group, ribosomal subgroup 16SrI‐C. Identical analyses of the ribosomal protein genes rpl22 and rps3 were used for further classification and revealed affiliation of the phytoplasmas with the rpIC subgroups. This is the first report of naturally occurring clover phyllody phytoplasma in A. graveolens in both the Czech Republic and worldwide.