Molecular characterization of phytoplasmas in lilies with fasciation in the Czech Republic

Lilium spp. with symptoms of severe fasciation were observed in Southern and central Bohemia during the period 1999-2003. Nucleic acids extracted from symptomatic and asymptomatic plants were used in nested-PCR assays with primers amplifying 16S-23S rRNA sequences specific for phytoplasmas. The subsequent nested-PCR with phytoplasma group-specific primers followed by RFLP analyses and the 16S ribosomal gene sequencing, allowed classification of the detected phytoplasmas in the aster yellows group, subgroups 16SrI-B and 16SrI-C alone, and in mixed infection. Samples infected by 16SrI-C phytoplasmas showed different overlapping RFLP profiles after TruI digestion of R16F2/R2 amplicons. Two of these amplicons were sequenced, one of them directly and the other after cloning; sequence analyses and blast alignment confirmed the presence of two different overlapping patterns in samples studied. The sequences obtained were closely related, respectively, to operon A and operon B ribosomal sequences of the clover phyllody phytoplasma. Direct PCR followed by RFLP analyses of the tuf gene with two restriction enzymes showed no differences from reference strain of subgroup 16SrI-C. Infection with aster yellows phytoplasmas of 16SrI-B subgroup in asymptomatic lilies cv. Sunray was also detected.     

Identification of aster yellows phytoplasma in garlic and green onion by PCR-based methods

In the summer of 1999, typical yellows-type symptoms were observed on garlic and green onion plants in a number of gardens and plots around Edmonton, Alberta, Canada. DNA was extracted from leaf tissues of evidently healthy and infected plants. DNA amplifications were conducted on these samples, using two primer pairs, R16F2n/R2 and R16(1)F1/R1, derived from phytoplasma rDNA sequences. DNA samples of aster yellows (AY), lime witches'-broom (LWB) and potato witches'-broom (PWB) phytoplasmas served as controls and were used to determine group relatedness. In a direct polymerase chain reaction (PCR) assay, DNA amplification with universal primer pair R16F2n/R2 gave the expected amplified products of 1.2 kb. Dilution (1/40) of each of the latter products were used as template and nested with specific primer pair R16(1)F1/R1. An expected PCR product of 1.1 kb was obtained from each phytoplasma-infected garlic and green onion samples, LWB and AY phytoplasmas but not from PWB phytoplasma. An aliquot from each amplification product (1.2 kb) with universal primers was subjected to PCR-based restriction fragment length polymorphism (RFLP) to identify phytoplasma isolates, using four restriction endonucleases (AluI, KpnI, MseI and RsaI). DNA amplification with specific primer pair R16(1)F1/R1 and RFLP analysis indicated the presence of AY phytoplasma in the infected garlic and green onion samples. These results suggest that AY phytoplasma in garlic and green onion samples belong to the subgroup 16Sr1-A.     

Molecular Characterization of Aster Yellows Phytoplasma Associated with Valerian and Sowthistle Plants by PCR–RFLP Analyses

In Alberta, Canada, valerian grown for medicinal purposes and sowthistle, a common weed, showed typical aster yellows symptoms. Molecular diagnosis was made using a universal primer pair (P1 / P7) designed to amplify the entire 16S rRNA gene and the 16 / 23S intergenic spacer region in a direct polymerase chain reaction (PCR) assay. This primer pair amplified the DNA samples from valerian and sowthistle and reference controls (AY‐27, CP, PWB, AY of canola, LWB). They produced the expected PCR products of 1.8 kb, which were diluted and used as templates in a nested PCR. Two primer pairs R16F2n / R2 and P3 / P7 amplified the DNA templates giving PCR products of 1.2 and 0.32 kb, respectively. No PCR product was obtained with either set of primers and DNA isolated from healthy plants. Restriction fragment length polymorphism (RFLP) was used to analyse the partial 16S rDNA sequences (1.2 kb) of all phytoplasma DNA samples after restriction with four endonucleases (AluI, HhaI, MseI and RsaI). The restriction patterns of these strains were found to be identical with the RFLP pattern of the AY phytoplasma reference control (AY‐27 strain). Based on the RFLP data, the two strains are members of subgroup A of the AY 16Sr1 group. We report here the first molecular study on the association of AY phytoplasmas with valerian and sowthistle plants.     

Detection and Identification of an Elm Yellows Group Phytoplasma Associated with Camellia in China

In 2012, yellowing of camellias was observed in Tai'an in Shandong province, China. Transmission electron microscopy (TEM) revealed phytoplasma in the phloem sieve tube elements of symptomatic plants. A specific fragment of phytoplasma 16S rRNA gene was amplified by polymerase chain reaction (PCR) using the universal phytoplasma primers P1/P7 followed by R16F2n/R16R2. Sequence and restriction fragment length polymorphism (RFLP) analyses allowed us to classify the detected phytoplasma into the elm yellows (EY) group (16SrV), subgroup 16SrV‐B. Sequence analyses of the ribosomal protein (rp) gene confirmed a close relationship with phytoplasmas belonging to the rpV‐C subgroup. Thus, the phytoplasma associated with yellows disease in camellia, designated as ‘CY’, is a member of the 16SrV‐B subgroup. This is the first report of phytoplasma associated with camellia.     

Multigene analysis for differentiation of aster yellows phytoplasmas infecting carrots in Serbia

During a survey of large carrot fields in Serbia, plants showing leaf reddening and/or yellowing, adventitious shoot production and reduction in taproot size and quality were observed in a low percentage of plants. To verify phytoplasma association with the described symptoms and to carry out pathogen differentiation, PCR assays followed by restriction fragment length polymorphism (RFLP) analyses and/or sequencing of phytoplasma 16Sr DNA and ribosomal protein genes l22 and s3 , tuf , putative aa kinase plus ribosomal recycling factor genes and DNA helicase gene were carried out. Phytoplasmas belonging to 16SrI-A and 16SrI-B ribosomal subgroups and to rpI-A and rpI-B ribosomal protein subgroups, respectively, were identified by RFLP analyses in 13 of 15 symptomatic plants tested. No amplification was obtained with non-symptomatic carrot samples. The identification was confirmed by sequence analyses of the phytoplasma genes studied. In two carrot samples, presence of interoperon sequence heterogeneity was detected and phytoplasma strains were identified as belonging to 16SrI group but were not assigned to any 16S rRNA or ribosomal protein subgroup. This research allowed the first molecular identification of phytoplasmas infecting carrot in Serbia using several molecular markers, and it indicates that under field conditions in non-epidemic outbreaks a certain amount of genetic mutation may occur in conserved genes of these prokaryotes.     

Detection of aster yellows phytoplasma in false flax based on PCR and RFLP

False flax (Camelina sativa L.) plants were found to be infected with a yellows-type disease caused by a phytoplasma in experimental plots at the Edmonton Research station. Alberta, Canada. Typical phytoplasmas were detected in the phloem cells in ultrathin sections from leaf midrib tissues examined by electron microscopy. These observations were supported by polymerase chain reaction (PCR) using two primer pairs, R16 F2n/R2 and R16(1)F1/R1, derived from phytoplasma rDNA sequences. Aster yellows (AY) and potato witches'-broom (PWB) phytoplasma DNA samples served as controls and were used to study group relatedness. In a direct PCR assay, DNA amplification with universal primer pair R16F2n/R2 gave the expected PCR products of 1.2 kb. Based on a nested-PCR assay using the latter PCR products as templates, and a specific primer pair, R16(1)F1/R1, designed on the basis of AY phytoplasma rDNA sequences, a PCR product of 1.1 kb was obtained from each phytoplasma-infected false flax and AY sample, but not from PWB phytoplasma and healthy controls. DNA amplification with specific primer pair R16(1)F1/R1 and restriction fragment length polymorphism indicated the presence of AY phytoplasma in the infected false flax sample. This is the first reported characterization of AY phytoplasma in false flax.     

First Report of Aster Yellows Phytoplasma in Goldenrain Tree (Koelreuteria paniculata) in Korea

Aster yellows phytoplasma was detected for the first time in goldenrain tree (Koelreuteria paniculata) growing in Sinpyeong‐myeon, Jeollabuk‐do, South Korea. DNA was extracted from the infected leaf samples and part of the 16S rDNA, rp operon and tuf gene were amplified using R16F2n/R2 and gene‐specific primers. The sequence analysis showed that the phytoplasma was closely related (99%) to members of the Aster Yellows (AY) group, and belonging to 16Sr I, subgroup B. Moreover, the 16S rDNA sequences of the isolate showed 88–96% identity with members of other 16Sr and undesignated groups. Based on the sequence identity and phylogenetic studies, it was confirmed that phytoplasma infecting goldenrain tree in South Korea belongs to the AY group.     

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.     

Characterisation of phytoplasma (16SrVI) associated with little leaf disease of Portulaca grandiflora – An in silico analysis

A new severe little leaf disease was observed on P. grandiflora, popular as Moss-rose Purslane, widely grown in temperate zones. Characteristic symptoms, ultrastructural studies, antibiotic response and amplification of 16S ribosomal DNA fragments (about 1.5 kb) by polymerase chain reaction (PCR) from infected samples, suspect the involvement of phytoplasma as a pathogen. Nested PCR product, 1.2 kb, with primer pairs R16F2n/R16R2 used for cloning and sequencing. Comparision of the 16S rRNA gene sequences showed that the causal, PLL phytoplasma, is very close (98%) to Indian brinjal little leaf (EF186820) and “Candidatus Phytoplasma trifolii” (AY390261), 16SrVI group phytoplasmas, previously reported from India and Canada respectively. Here, the status of PLL (EF651786) is verified by computer-simulated restriction fragment length polymorphism analysis of 16S rRNA genes of the F2n/R2 sequences of closely related strains of the 16SrVI group using 17 restriction enzymes.     

Detection and Molecular Characterization of ‘Candidatus Phytoplasma asteris’ in European Hazel (Corylus avellana) in Poland

Stunted European hazel (Corylus avellana L.) plants showing leaf yellowing were observed in south‐eastern Poland. Phytoplasma‐specific primers P1/P7 and R16F2n/R16R2, as well as primers specific for aster yellows (16SrI), X‐disease (16SrIII) and apple proliferation (16SrX) groups were singly used in nested polymerase chain reaction (PCR) to amplify the 16S rDNA from 22 symptomatic and asymptomatic hazel plants. Restriction fragment length polymorphism with MseI, HhaI, RsaI and BfaI enzymes of the 16S rRNA gene fragments amplified with the primers R16F2n/R16R2 from three symptomatic hazel plants of cvs Katalonski, Webba and Halle revealed patterns identical to those from the AY1 strain related to ‘Candidatus Phytoplasma asteris’. The nucleotide sequence analysis confirmed this result. This is the first report of the natural occurrence of ‘Ca. P. asteris’ in European hazel in Poland.     

Association of phytoplasmas and viruses with malformed clovers

Plants of Trifolium spp. exhibiting two different kinds of symptoms--phyllody associated with yellowing/reddening, and dwarf growth habit without floral abnormalities--were observed in several areas of the Czechia. Nested polymerase chain reaction (PCR) with phytoplasma specific primers, and restriction fragment length polymorphism (RFLP) analyses of 16SrDNA revealed that phyllody of T. repens was associated with phytoplasmas belonging to the 16SrI-C subgroup. Similar symptoms in T. hybridum and T. pratense plants revealed the presence of phytoplasmas belonging to two subgroups: 16SrI-C and 16SrIII-B. Dwarf disease of cultivated T. pratense plants was associated with more than one agent: 11 of 20 plants examined by PCR/RFLP analysis revealed the presence of phytoplasmas belonging to four distinct subgroups: 16SrI-B, 16SrI-C, 16SrIII-B and 16SrX-A. Moreover, two kinds of bacilliform virions were observed in ultrathin sections of 15 T. pratense plants. Particles occurred mostly in the parenchymatous cells of vascular bundles and were located in the cytoplasm as aggregates within an extended network of membranous cisternae. Phytoplasmas and rhabdoviruses occurred singly, and both together or in co-presence with filamentous virus-like particles.     

Association of ‘<Emphasis Type="Italic">Candidatus</Emphasis> Phytoplasma asteris’ with yellowing and phyllody of <Emphasis Type="Italic">Plantago lanceolata</Emphasis>

Long plantains (Plantago lanceolata L.) with symptoms resembling those associated with phytoplasma infection were observed repeatedly during the period 2000–2008 in southern Bohemia (Czech Republic). The symptoms of the plants were leaf yellowing, stunted growth, flower phyllody and lack of seed production. Transmission electron microscopy showed phytoplasmas in the sieve cells of affected plants but not in healthy ones. Association of phytoplasmas with the disease was confirmed by polymerase chain reaction using phytoplasma-specific universal ribosomal primers R16F2n/R16R2. An amplification product of the expected size (1.2 kb) was observed in all samples of the symptomatic long plantains. The restriction profiles obtained from digestion of the PCR products with three endonucleases (AluI, HhaI, MseI) showed that the phytoplasmas infecting long plantains in the Czech Republic were indistinguishable from those belonging to the aster yellows group (subgroup 16SrI-B). Sequence analysis of 1748 bp of the ribosomal operon indicated that the closest related phytoplasma was that associated with ‘Rehmannia glutinosa var. purpurea’, originating also in Bohemia. This is the first report of the natural occurrence of ‘Candidatus Phytoplasma asteris’ in plants of P. lanceolata.     

Grapevine yellows in Northern Italy: molecular identification of Flavescence dorée phytoplasma strains and of Bois Noir phytoplasmas

AIMS: Verify the presence and the molecular identity of phytoplasmas in Northern and Central Italy vineyards where yellows diseases are widespread. METHODS AND RESULTS: Phytoplasma presence and identity were determined by PCR/RFLP analyses on 16S ribosomal gene testing 1424 symptomatic samples. The 65% of samples resulted phytoplasma infected; in particular 256 samples were found positive to phytoplasmas belonging to group 16SrV (mainly Flavescence dorée associated), and the remaining 37% was infected by phytoplasmas belonging to ribosomal subgroup 16SrXII-A (Stolbur or Bois Noir associated). 16SrV ribosomal group representative strains were further typed for variability in SecY and rpS3 genes. The results showed the presence of phytoplasmas belonging to 16SrV-C, 16SrV-D and to a lesser extent, 16SrV-A subgroup. CONCLUSIONS: Possible relationships between genetic polymorphisms of phytoplasma strains belonging to subgroup 16SrV-C and their geographic distribution and/or epidemic situations were detected. SIGNIFICANCE AND IMPACT OF THE STUDY: Bois Noir and Flavescence dorée phytoplasmas are present in significant percentages in the areas under investigation. Molecular tools allowed to identify phytoplasma-infected plants and the genes employed as polymorphism markers resulted useful in distinguishing and monitoring the spreading of the diseases associated with diverse phytoplasmas belonging to 16SrV subgroup in vineyards.     

Molecular characterization of ‘Clover proliferation’ phytoplasma subgroup-D (16SrVI-D) associated with vegetables crops in India

Nine vegetable plants species exhibiting phytoplasma suspected symptoms of white/purple leaf, little leaf, flat stem, witches’ broom, phyllody and leaf yellowing were observed in experimental fields at Indian Agricultural Research Institute, New Delhi from December 2015 to July 2016. Total DNA extracted from the three healthy and three symptomatic leaves of all the nine vegetables were subjected to PCR assays using phytoplasma specific primers P1/P7 followed by R16F2n/R16R2 and 3Far/3Rev to amplify the 16S rDNA fragments. No amplifications of DNA were observed in first round PCR assays with primer pair P1/P7 from any of the symptomatic samples. However, phytoplasma DNA specific fragments of ~ 1.3 kb were amplified from Apium graveolens L. (two isolates), Brassica oleracea vr. capitata L. (one isolate) and Solanum melongena L. (one isolate) by using 3Far/3Rev primer pair and 1.2 kb fragment was amplified from Lactuca sativa L. (one isolate) by using R16F2n/R16R2 primer pair. No DNA amplification was seen in other symptomatic vegetable samples of tomato, carrot, cucurbit, bitter gourd and Amaranthus species utilizing either P1/P7 primer pair followed by 3Far/3Rev or R16F2n/R16R2 primer pairs. Out of three leafhopper species collected from the symptomatic vegetable fields, only Hishimonus phycitis was found positive for association of phytoplasma. No DNA amplifications were observed in healthy plant samples and insects collected from non-symptomatic fields. Comparative sequence comparison analyses of 16S rDNA of positive found vegetable phytoplasma strains revealed 100% sequence identities among each other and with phytoplasma strains of ‘clover proliferation’ (16SrVI) group. Phytoplasma sequences, virtual RFLPs and phylogenetic analyses of 16S rDNA sequence comparison confirmed the identification of 16SrVI subgroup D strain of phytoplasmas in four vegetables and one leafhopper (HP) species. Further virtual RFLP analysis of 16S rDNA sequence of the vegetables phytoplasma strains confirmed their taxonomic classification with strains of ‘clover proliferation’ subgroup D. Since, H. phycitis feeding on symptomatic vegetable species in the study was also tested positive for the 16SrVI phytoplasma subgroup-D as of vegetables; it may act as potent natural reservoir of 16SrVI-D subgroup of phytoplasmas infecting vegetable and other important agricultural crops.     

Aster Yellows Phytoplasma Identified in Scentless Chamomile by Microscopical Examinations and Molecular Characterization

Scentless chamomile (Matricaria perforata Mérat) plants were commonly found infected with a yellows-type disease caused by phytoplasma in several fields in Alberta, Canada. Typical phytoplasmas were detected in the phloem cells in ultrathin sections from leaf, stem, root and flower petiole tissues examined by electron microscopy. Application of 4′6-diamidino-2-phenylindole- 2HCl (DAPI) staining techniques confirmed the presence of the phytoplasma in these tissues. These observations were supported by polymerase chain reaction (PCR) assays, using two primer pairs, P1/P6 and R16(1)F1/R1, derived from phytoplasma rDNA sequences. Aster yellows and potato witches′-broom (PWB) DNA phytoplasma samples served as positive controls and were used to study group relatedness. In a direct PCR assay, DNA amplification with universal primer pair P1/P6 gave the expected PCR products of 1.5 kb. Based on a nested-PCR assay using the latter PCR products, as templates, and a specific primer pair R16(1)F1/R1 designed on the basis of AY phytoplasma rDNA sequences, a PCR product of 1.1 kb was obtained from each phytoplasma-infected chamomile and AY samples but not from PWB phytoplasma and healthy chamomile controls. DNA amplification with specific primer pair R16(1)F1/R1 and restriction fragment length polymorphism indicated the presence of AY phytoplasma in the infected scentless chamomile sample.     

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.     

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.     

Occurrence and Characterization of a 16SrII‐D Subgroup Phytoplasma Associated with Parsley Witches’ Broom Disease in Iran

During 2010–2013 surveys for the presence of phytoplasma diseases in Yazd province (Iran), a parsley witches’ broom (PrWB) disease was observed. Characteristic symptoms were excessive development of short spindly shoots from crown buds, little leaf, yellowing, witches’ broom, stunting, flower virescence and phyllody. The disease causative agent was dodder transmitted from symptomatic parsley to periwinkle and from periwinkle to periwinkle by grafting inducing phytoplasma‐type symptoms. Expected length DNA fragments of nearly 1800 and 1250 bp were, respectively, amplified from naturally infected parsley and experimentally inoculated periwinkle plants in direct polymerase chain reaction (PCR) using phytoplasma primer pair P1/P7 or nested PCR using the same primer pair followed by R16F2n/R16R2 primers. Restriction fragment length polymorphism and phylogenetic analyses of 16S rRNA gene sequences showed that the phytoplasma associated with PrWB disease in Yazd province belong to 16SrII‐D phytoplasma subgroup. This is the first report of association of a 16SrII‐related phytoplasma with PrWB disease in Iran.     

Molecular study of two distinct phytoplasma species associated with streak yellows of date palm in Iran

A disease with symptoms similar to palm lethal yellowing was noticed in the early 2013 in Khuzestan Province (Iran) in date palm (Phoenix dactylifera). Infected trees displaying symptoms of streak yellows and varied in the incidence and severity of yellowing. A study was initiated to determine whether phytoplasma was the causal agent. Polymerase chain reaction–restriction fragment length polymorphism (PCR‐RFLP) methods using universal phytoplasma primers pairs R16mF1/mR1 and M1/M2 were employed to detect putative phytoplasma(s) associated with date palm trees. Nested PCR using universal primers revealed that 40 out of 53 trees were positive for phytoplasma while asymptomatic date palms from another location (controls) tested negative. RFLP analyses and DNA sequencing of 16S rDNA indicated that the presence of two different phytoplasmas most closely related to clover proliferation (CP) phytoplasma (group 16SrVI) and ash yellows (AY) phytoplasma (group 16SrVII). Sequence analysis confirmed that palm streak yellows phytoplasmas in each group were uniform and to be phylogenetically closest to “CandidatusP. fraxini” (MF374755) and “Ca. P. trifolii” isolate Rus‐CP361Fc1 (KX773529). Result of RFLP analysis of secA gene of positive samples using TruI and TaqI endonuclease is in agreement with rDNA analysis. On this basis, both strains were classified as members of subgroups 16SrVI‐A and 16SrVII‐A. This is the first report of a phytoplasma related to CP and AY phytoplasma causing date palm yellows disease symptoms.