Detection and seed transmission of Bermudagrass phytoplasma in maize in Turkey

During 2017, maize cultivation areas in the provinces of Adana and Kahramanmara? (Turkey) were surveyed to inspect maize plants with symptoms similar to those associated with of phytoplasma disease, that is, yellowing, short internodes and small corncobs. Thirty fields were inspected and two hundred samples from symptomatic and asymptomatic plants were collected, together with insects considered as potential vectors of phytoplasmas. All samples were assayed by polymerase chain reaction (PCR) and subsequently analysed by restriction fragment length polymorphism and sequencing to identify the phytoplasmas detected in the plant material and insects. Results of laboratory assays and phylogenetic analyses showed that the Bermudagrass white leaf phytoplasma ('Candidatus Phytoplasma cynodontis') was present in both maize plants and seeds, showing 99% sequence identity with other reported phytoplasma strains from GenBank, whereas no PCR amplifications were obtained from tested insects. The seeds of infected plants, sown in an insect‐proof screenhouse, produced plantlets that were found PCR‐positive for the Bermudagrass white leaf phytoplasma, indicating its seed transmission.     

Detection, characterisation and transmission by Macrosteles leafhoppers of watercress yellows phytoplasma in Hawaii

A new yellows disease of watercress (Nasturtium officinale) in Hawaii has symptoms of reduced leaf size, leaf yellowing and crinkling, and occasionally witches’ brooms. This disease is found on all watercress farms on Oahu but has not yet been found on other Hawaiian islands. Watercress plants were tested for phytoplasma infection by polymerase chain reaction assays using phytoplasma‐specific primers. Amplicons of the expected sizes were produced from all symptomatic plants but not from healthy plants raised from seed. Phylogenetic analysis of the 16S rRNA gene indicated that watercress yellows was caused by a phytoplasma in the aster yellows group, with sequence similarity to onion yellows from Japan. Six weed species collected from the vicinity of affected watercress farms, Amaranth sp., Eclipta prostrata, Emilia sonchifolia, Plantago major, Myriophyllum aquaticum and Sonchus oleraceus, were also determined to be hosts of this phytoplasma. Leafhoppers, identified as Macrosteles sp. (Hemiptera, Cicadellidae), collected from symptomatic watercress transmitted this phytoplasma to watercress, plantain and lettuce (Lactuca sativa) in greenhouse experiments.     

Detection of a 16SrXII phytoplasma associated with sugarcane yellow leaf syndrome in India

Phytoplasma strain was detected in leaves of sugarcane in India exhibiting symptoms of yellowing of midribs. A phytoplasma characteristic 1.2 kb rDNA PCR product was amplified from DNAs of all diseased samples but not in healthy sugarcane plants tested using phytoplasma universal primer pairs P1/P7 and f5U/r3U. Restriction fragment length polymorphism (RFLP) analysis of amplified 16S rDNA indicated that diseased sugarcane was infected by phytoplasma. The 16S rDNA sequence of the Indian sugarcane yellow leaf phytoplasma (SCYLP) showed the closest identity (99%) to that of SCYLP in Cuba identified as Macroptilium lathyroides (AY725233), which belongs to 16SrXII (Stolbur group). This is the first record of the detection of SCYLP, and identification of the 16SrXII group of phytoplasma associated with yellow leaf syndrome (YLS) in India.     

Identification,occurrence, incidence and transmission of phytoplasma associated with Petunia violacea witches’ broom in Iran

A petunia witches’ broom (PvWB) disease, characterized by phyllody, virescence, witches’ broom, little leaf and yellowing, was observed in municipal lands and parks in Bandar Abbas, Hormozgan province, Iran. The disease was present with an average incidence of 20%. PCR and sequencing analysis carried out on selected samples from symptomatic plants showed the presence of a phytoplasma associated with the disease. The molecular comparison of the 16S ribosomal gene indicated 99% sequence identity with the one of “Candidatus Phytoplasma australasia”. This phytoplasma was transmitted to healthy petunia plants under experimental conditions by the leafhopper Orosius albicinctus that was then demonstrated to be a vector of this phytoplasma.     

Detection and molecular characterization of an aster yellows phytoplasma in poker statice and Queen Anne's lace in Alberta, Canada

Queen Anne's lace and poker statice plants were found with a yellows-type disease with typical phytoplasma symptoms in an experimental farm near Brooks, Alberta in 1996. Phytoplasma bodies were detected by transmission electron microscopy in phloem cells of symptomatic plants, but not in healthy plants. The presence of a phytoplasma was confirmed by analysis with the polymerase chain reaction. Using a pair of universal primer sequences derived from phytoplasma 16S rRNA, an amplified product of the expected size (1.2 kb) was observed in samples from infected plants, but not in asymptomatic plants. Sequence analysis of the PCR products from the 16S/23S rDNA intergenic spacer region indicated that the two phytoplasma isolates in Queen Anne's lace and poker statice are genetically closely related to the western aster yellows phytoplasma.     

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.     

Occurrence,identification and transmission of the phytoplasma associated with tomato big bud disease and identification of its vector and weed host in Pakistan

Abstract

Tomato (Solanum lycopersicum L.) plants showing stunting, big bud, leaves yellowing or reddening and witches’-broom symptoms were observed since 2009 in Pakistan. A weed Parthenium hysterophorus grown in and around tomato fields also exhibited witches’-broom like symptoms. Fluorescence light microscopy of hand-cut stem stalk sections treated with Dienes’ stain showed blue areas in the phloem region of both tomato and P. hysterophorus symptomatic plants that indicated the association of phytoplasma with the complex. Amplification of 1.2?kb 16S rDNA fragment in nested PCR confirmed that the symptomatic tomato and P. hysterophorus plants are infected by a phytoplasma. Partial sequencing of 16S rRNA (GenBank accession: LT671581 and LT671583) and virtual restriction fragment length polymorphism confirmed that the phytoplasma associated with both plant species had the greatest homology to 16SrII-D subgroup. Disease was successfully transmitted by grafting and leafhopper Orosius albicinctus in tomato plants. This is the first report of natural occurrence of 16SrII-D phytoplasma in tomatoes and a weed P. hysterophorus in Pakistan.     

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.     

Phytoplasma distribution in coconut palms affected by lethal yellowing disease

Lethal yellowing (LY), the most devastating disease affecting the coconut palm in America, is caused by phytoplasmas known to be distributed in different parts of infected plants. However, no comprehensive reports exist on the phytoplasma distribution. This study refers to the detection of LY phytoplasma DNA using PCR in different coconut plant parts, throughout the development of the disease. Sample analysis of positive palms taken at different stages of disease development (either symptomatic or symptomless) showed differences in the percentage of LY detection between plant parts. Some parts showed a very high level of LY DNA (stem, young leaves, inflorescences, stem apex and root apex), low levels were found in the intermediate leaves and roots without apex, whereas no LY phytoplasma DNA was detected in mature leaves. The detection percentage of LY phytoplasma DNA was lowest in symptomless‐infected palms for all parts, except the stem, where phytoplasma accumulations were consistently detected. This pattern of detection among parts is consistent with the hypothesis that phytoplasmas move from photosynthate source tissues to sink tissues via the phloem mass flow process. The accumulations in the (lower) stem, prior to the appearance of symptoms, suggest that this part of the palm is where phytoplasmas first move from leaves after foliar feeding by vectors and in which they probably multiply and distribute to other palm parts, including roots. Embryos from infected palms were analysed by nested‐PCR and 28% of 394 embryos were positive. Phytoplasma DNA was detected in embryos from fruit on any of the fruiting bunches regardless the age, but no pattern of quantitative distribution throughout the bunch developmental stages was observed. Germination of seeds from LY‐positive symptomatic palms was 58% and from LY‐negative symptomless palms were 71%. No phytoplasma was detected in seedlings tested from both symptomatic and non‐symptomatic palms. Seedlings tested after 2 years did not develop LY symptoms or eventually died.     

Detection and characterisation of phytoplasma strains associated with field bindweed witches’ broom disease in Iran

Abstract

During 2013–2015 surveys in Fars, Lorestan and Yazd provinces (Iran), a field bindweed witches’ broom (FBWB) disease was observed. The main symptoms were reduction of leaves size, yellowing, internode shortening, witches’ broom and stunting. The agent of FBWB was dodder transmitted to periwinkle plants inducing phytoplasma-type symptoms. Amplifications of nearly 1.8 and 1.2 kbp were, respectively, obtained from 15 symptomatic bindweed plants and 28 symptomatic dodder-inoculated periwinkles. Virtual RFLP analyses showed that the phytoplasma detected belonged to 16SrXII-A subgroup, and it was the same in all the samples examined; phylogenetic analyses confirmed it as a ‘Candidatus Phytoplasma solani’-related strain. This is the first report of 16SrXII-A phytoplasmas presence in bindweed plants showing witches’ broom symptoms in Fars, Lorestan and Yazd provinces. As a perennial widespread weed, it may act as a 16SrXII-A phytoplasma source for alfalfa, grapevine, Sophora alopecuroides, tomato, hemp and Japanese spindle reported diseases in these Iranian provinces.     

Characterization of 16SrII-D subgroup associated phytoplasmas in new host plants in Egypt

Samples of three plant species displaying phytoplasma symptoms were collected from Kafrelsheikh and Al-Gharbia governorates during 2014. Witches’ broom and virescence symptoms were observed in periwinkle (Catharanthus roseus). Onion (Allium cepa) plants showed yellowing, streaks and twisting and Opuntia abjecta with proliferation and cylindrical of cladodes. Total DNA was extracted from symptomatic and asymptomatic plants, and phytoplasma were detected in all 12 symptomatic plants collected through direct and nested PCR assays with primers P1/P7 and R16F2n/R16R2. The results of phylogenetic analysis revealed that the phytoplasma isolates belong to 16SrII group. With a nucleotide identity greater than 98.7% with three members of 16SrII group, Papaya yellow crinkle, Y10097; “Ca. P. aurantifolia”, U15442; and peanut witches’ broom, Al33765, the strains identified in this study are “Ca. P. aurantifolia”-related strains. Virtual RFLP analysis of the 16S rRNA gene sequences with 17 restriction enzymes confirmed that the phytoplasma isolates belong to the “Candidatus Phytoplasma australasia” 16SrII-D subgroup. To the best of our knowledge, periwinkle, onion and Opuntia abjecta are considered new hosts for 16SrII group in Egypt.     

Association of a phytoplasma with a yellow leaf syndrome of sugarcane in Africa

Evidence is presented for the association of a phytoplasma, provisionally named sugarcane yellows phytoplasma (ScYP), in sugarcane affected by a yellow leaf syndrome. The phytoplasma was consistently detected in leaves of more than 40 varieties from eight African countries. It was present in all symptomatic as well as some asymptomatic field grown cane samples but not in plants grown from true seed, and it was also observed in phloem sieve tubes by transmission electron microscopy. Phytoplasma 16S rDNA was confirmed by PCR, and restriction fragment analysis using Rsal and Haelll confirmed that PCR-amplified products were of phytoplasma rather than of plant or of other pathogen origin. Sequences obtained from the intergenic spacer region, between the 16S and 23S rDNA genes, confirmed the identity of the phytoplasma as belonging to the western X group of phytoplasmas.     

Detection and Identification of Phytoplasmas in Pomegranate Trees with Yellows Symptoms

Symptoms resembling those associated with phytoplasma presence were observed in pomegranate (Punica granatum L.) trees in June 2012 in the Aegean Region of Turkey (Ayd?n province). The trees exhibiting yellowing, reduced vigour, deformations and reddening of the leaves and die‐back symptoms were analysed to verify phytoplasma presence. Total nucleic acids were extracted from fresh leaf midribs and phloem tissue from young branches of ten symptomatic and five asymptomatic plants. Nested polymerase chain reaction assays using universal phytoplasma‐specific 16S rRNA and tuf gene primers were performed. Amplicons were digested with Tru1I, Tsp509I and HhaI restriction enzymes, according to the primer pair employed. The phytoplasma profiles were identical to each other and to aster yellows (16SrI‐B) strain when digestion was carried out on 16Sr(I)F1/R1 amplicons. However, one of the samples showed mixed profiles indicating that 16SrI‐B and 16SrXII‐A phytoplasmas were present when M1/M2 amplicons were digested, the reamplification of this sample with tuf cocktail primers allowed to verify the presence of a 16SrXII‐A profile. One pomegranate aster yellows strain AY‐PG from 16S rRNA gene and the 16SrXII‐A amplicon from tuf gene designed strain STOL‐PG were directly sequenced and deposited in GenBank under the Accession Numbers KJ818293 and KP161063, respectively. To our knowledge, this is the first report of 16SrI‐B and 16SrXII‐A phytoplasmas in pomegranate trees.     

A new phytoplasma detected in the South Australian native perennial shrub, Allocasuarina muelleriana

Allocasuarina muelleriana shrubs growing in natural sclerophyll roadside vegetation near Willalooka in the upper south‐east of South Australia have a high incidence of a yellowing disorder in either all or part of the foliage, combined in some cases with a shortening and curling of the leaf‐bearing stems. Samples from symptomatic and adjacent asymptomatic plants were tested for phytoplasmas by the polymerase chain reaction (PCR) assay. All but one asymptomatic plant were negative for phytoplasmas, whereas about half of the symptomatic plants were positive. Restriction fragment polymorphism analysis of PCR products indicated that the phytoplasma was related to the buckthorn witches.‐broom (BWB) and apple proliferation (AP) groups of phytoplasmas, members of which have not been previously reported in Australia. Further evidence from the sequence of the 16S rRNA gene and the use of PCR primers specific to the AP and pear decline (PD) phytoplasmas confirmed the close relationship to the BWB and AP group phytoplasmas.     

Detection and Identification of Aster Yellows Group Phytoplasma (16SrI‐C) Associated with Peach Red Leaf Disease

In 2011, typical symptoms suggestive of phytoplasma infection such as reddening of leaves were observed in peach trees in Fuping, Shaanxi Province, China. Phytoplasma‐like bodies were observed by transmission electron microscope in the petiole tissues of symptomatic peach trees. Products of c. 1.2 kb were generated from all symptomatic peach leaf samples by a nested polymerase chain reaction using phytoplasma universal primer pairs P1?P7 and R16F2n?R16R2, whereas no such amplicon was obtained from healthy samples. Results of phylogenetic analysis and restriction fragment length polymorphism suggested that the phytoplasma associated with such peach red leaf disease was a member of subgroup 16SrI‐C. To our knowledge, this is the first record of 16SrI‐C subgroup phytoplasma occurred in peach tree in China.     

Occurrence and identification of aster yellows related phytoplasma in Gladiolus in Poland

In 1996–1998 on Gladiolus plants cultivated in Poland severe symptoms were observed. The symptoms included chlorosis of the youngest leaves, yellowing and malformation of flower spices, flower discoloration and virescence. The affected corms kept in cold storage developed premature multiple sprouts weak and pale in color. Their root formation was strongly inhibited. Electron microscopy examination of the ultra-thin sections of the leaves and roots of diseased plants showed necrosis and collapsing of sieve tubes and companion cells, reduction of phloem and xylem strands as well as decrease of the number and diameter of xylem vessels. Numerous polymorphic bodies were observed in the phloem and parenchyma cells of affected gladioli. PCR amplification using universal phytoplasma primers rU3 and fU5 directed to ribosomal sequences and RFLP analysis of the amplified rDNA were used to identify the phytoplasma causing yellow disease in Poland. Specific product of about 880 bp was obtained, providing evidence of phytoplasma infection. RFLP analysis of the PCR product done with restriction enzyme AluI showed that the diseased gladioli were infected by phytoplasma very similar or identical with American aster yellows phytoplasma.     

First detection of “Candidatus Phytoplasma asteris” - and “Candidatus Phytoplasma solani”-related strains in fig trees

In July 2017, a survey was conducted in a fig collection plot at Locorotondo (south of Italy) to investigate the possible presence of phytoplasmas in plants showing yellowing, deformed leaves, short internodes, mottling and mosaic. Samples were collected from symptomatic plants and tested by nested PCR assays using universal and specific primers to amplify the 16S rDNA of these prokaryotes. PCR results detected the presence of phytoplasma sequences in twenty plant samples that resulted clustering two phylogenetically distinct phytoplasmas, i.e., “Candidatus Phytoplasma asteris” and “Candidatus Phytoplasma solani” affiliated to 16SrI and 16SrXII ribosomal groups, respectively. The presence of phytoplasmas belonging to both ribosomal groups was confirmed with group specific quantitative PCR and RFLP assays on 16S ribosomal amplicons. Results of this study indicate for the first time the occurrence of phytoplasmas in fig; however, more work should be carried out to verify their association with the symptoms observed on diseased fig plants.     

Detection and Inoculation of Peanut Witches' Broom Phytoplasma (16SrII‐A) and Periwinkle Leaf Yellowing Phytoplasma (16SrI‐B) in Citrus Cultivars in Taiwan

To clarify the phytoplasma associated with Huanglongbing (HLB), a detection survey of phytoplasma in field citrus trees was performed using the standardized nested PCR assay with primer set P1/16S‐Sr and R16F2n/R16R2. The HLB‐diseased citrus trees with typical HLB symptoms showed a high detection of 89.7% (322/359) of HLB‐Las, while a low detection of phytoplasma at 1.1% (4/359) was examined in an HLB‐affected Wentan pummelo (Citrus grandis) tree (1/63) and Tahiti lime (C. latifolia) trees (3/53) that were co‐infected with HLB‐Las. The phytoplasma alone was also detected in a healthy Wentan pummelo tree (1/60) at a low incidence total of 0.3% (1/347). Healthy citrus plants were inoculated with the citrus phytoplasma (WP‐DL) by graft inoculation with phytoplasma‐infected pummelo scions. Positive detections of phytoplasma were monitored only in the Wentan pummelo plant 4 months and 3.5 years after inoculation, and no symptoms developed. The citrus phytoplasma infected and persistently survived in a low titre and at a very uneven distribution in citrus plants. Peanut witches' broom (PnWB) phytoplasma (16SrII‐A) and periwinkle leaf yellowing (PLY) phytoplasma belonging to the aster yellows group (16SrI‐B) maintained in periwinkle plants were inoculated into healthy citrus plants by dodder transmission. The PnWB phytoplasma showed infection through positive detection of the nested PCR assay in citrus plants and persistently survived without symptom expression up to 4 years after inoculation. Positive detections of the phytoplasma were found in a low titre and several incidences in the other inoculated citrus plants including Ponkan mandarin, Liucheng sweet orange, Eureka lemon and Hirami lemon. None of the phytoplasma‐infected citrus plants developed symptoms. Furthermore, artificial inoculation of PLY phytoplasma (16SrI‐B) into the healthy citrus plants demonstrated no infection. The citrus symptomless phytoplasma was identified to belong to the PnWB phytoplasma group (16SrII‐A).