Genetic diversity in the coconut lethal yellowing disease phytoplasmas of East Africa

DNA primers, based on the ribosomal sequences of lethal yellowing-type disease (LYD) phytoplasmas, were used to analyse genetic variation within the lethal yellowing-type diseases of coconut in East Africa. Samples were collected from palms in Kenya, Mozambique and high, medium and low disease incidence areas of Tanzania. The mollicute-specific primer pair P1 and P6 amplified a 1.5 kbp product from all diseased palms and no product from symptomless palms, indicating that phytoplasmas were associated with all of these diseases. However, the Rohde forward and Rohde reverse primers (a second rRNA primer pair designed to detect East African LYD-associated phytoplasmas) only amplified products from Tanzanian and Kenyan diseased palms and not from those of Mozambique. Conversely, primers Ghana 813 and AK-SR, designed for specific detection of coconut-associated phytoplasmas in West Africa, amplified products only from the Mozambique palms, indicating that the phytoplasma associated with LYD in Mozambique is more closely related to those from West Africa. This was supported by restriction enzyme digestion of PCR products. DNA sequencing of PCR products from phytoplasmas within Tanzania revealed no detectable differences in the rDNA sequences of isolates from high, medium and low incidence areas.     

Comparison of the ribosomal RNA operon from Texas Phoenix decline and lethal yellowing phytoplasmas

A comparison was made of the two palm yellows phytoplasmas affecting palms to determine if the entire ribosomal RNA operon portion of the phytoplasma genome, or portions thereof, could account for the observed palm host differences. Polymerase chain reaction (PCR) was used to amplify a 5.0?kb DNA fragment consisting of the entire ribosomal RNA operon from a subgroup 16SrIV-D phytoplasma that causes Texas Phoenix palm decline (TPD) in cabbage (Sabal palmetto) palm in west central Florida and from a subgroup 16SrIV-A phytoplasma that causes lethal yellowing (LY) in coconut (Cocos nucifera) palm in Jamaica. Before the PCR reaction, we sequenced by 454 sequencing a draft genome of the coconut LY phytoplasma, strain LYFL, that infects C. nucifera in Florida, and obtained from this draft sequence both copies of the entire ribosomal operon. Sequence analysis of the ribosomal RNA operons from both the LY and TPD phytoplasmas revealed the gene composition and orientation for the operons to be 5′16S rRNA-tRNA^Ile-23S rRNA-5S rRNA3′ and a tRNA^Val3′ downstream of the 5S rRNA gene. Based on molecular comparisons using the sequences of the ribosomal RNA operon, the TPD (16SrIV-D) strain was 98?% similar to the LY (16SrIV-A) strains.     

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.     

High diversity,expanding populations and purifying selection in phytoplasmas causing coconut lethal yellowing in Mozambique

In this study, the putative phytoplasma species causing coconut lethal yellowing disease in Mozambique and Tanzania were characterized. The 16S rRNA and secA genes were sequenced. Phylogenetic analysis revealed that Mozambican coconut phytoplasmas belong to three different types: ‘Candidatus Phytoplasma palmicola’ 16SrXXII‐A, a second strain that was previously isolated in Tanzania and Kenya (16SrIV‐C), and a third strain that was different from all known lethal yellowing phytoplasma species. The third strain potentially represents a novel species and is closely related to pine phytoplasma. Co‐infection with ‘Ca. Phytoplasma pini’‐related and ‘Ca. Phytoplasma palmicola’ 16SrXXII‐A strains was observed. Furthermore, sequence variation in ‘Ca. Phytoplasma palmicola’ at the population level was consistent with purifying selection and population expansion.     

Detection, identification and significance of phytoplasmas in grasses in northern Australia

Sugarcane yields have been severely reduced by white leaf and grassy shoot phytoplasma diseases in many parts of Asia. Australian sugarcane crops are not known to be affected by these diseases, but plant pathogenic phytoplasmas found in other introduced and native grasses in northern Australia could pose a serious threat to the Australian sugarcane industry. To further evaluate this threat, leaves from plants of 20 grass species, with and without symptoms, were collected during field surveys in northern Australia and tested to determine whether phytoplasmas were present and whether symptoms were reliable indicators of phytoplasma presence. Molecular tools were used to detect and characterize phytoplasmas. Four different phytoplasmas were found in seven grass species known to grow near healthy sugarcane crops. All the phytoplasmas were closely related to sugarcane white leaf phytoplasma (SCWL), one of the phytoplasmas that causes disease in sugarcane in Asia. Four of the host plant species and two of the phytoplasmas were new records. The relationship between symptoms and phytoplasma presence was poor. Because some plants with symptoms tested negative for phytoplasmas, a series of surveys was carried out in which flowers, leaves, roots and stems of two known host plant species, Whiteochloa cymbiformis and Sorghum stipoideum, were tested separately on nine occasions during two wet seasons. This was done to investigate the distribution of phytoplasmas within plants over time. Results showed that spatial and temporal variation of phytoplasmas occurred in these two host plant species. Hence, evaluation of disease distribution within a region requires repeated testing of all plant parts from plants without symptoms, as well as those with symptoms. To date, there is no report of a vector capable of transmitting to Australian sugarcane the phytoplasmas found in grasses in this study. If one is present, or occurs in the future, then native and introduced grasses could constitute a large reservoir of phytoplasma for vectors to draw on. This work provides an early warning for the sugarcane industry that the potential for infection exists.     

植原体黄化病的检疫及其防控技术研究进展

植物黄化病是一种常见的而且危害严重的病害.本文对几种由植原体引起的植物黄化病的症状、病原分类及其检疫技术和综合防控措施进行综述.     

Leafhoppers Exitianus atratus and Amplicephalus funzaensis transmit phytoplasmas of groups 16SrI and 16SrVII in Colombia

The phytoplasmas of groups 16SrI (‘Candidatus Phytoplasma asteris’) and 16SrVII (‘Ca. Phytoplasma fraxini’) have been associated with phytoplasma diseases in several urban tree species in Bogotá, Colombia and surrounding areas. The insect vectors responsible for this phytoplasma transmission are unknown. The objectives of this study were to test for the presence of phytoplasmas in leafhopper species (Cicadellidae) collected in areas with diseased trees and to determine the phytoplasma transmission ability of two of these species. Leafhoppers of nine species were collected at two sampling sites and tested by nested or double nested PCR using primers for the 16S rRNA gene. The amplicons were subjected to RFLP and/or sequencing analysis. Phytoplasmas of group 16SrI were detected in morphospecies MF05 (Haldorus sp.), group 16SrVII in MF07 (Xestocephalus desertorum), MF08 (Empoasca sp.) and MF09 (Typhlocybinae), and both groups 16SrI and 16SrVII in MF01 (Empoasca sp.), MF02 (Typhlocybinae), MF03 (Scaphytopius sp.), MF04 (Amplicephalus funzaensis) and MF06 (Exitianus atratus). Transmission tests to uninfected bean plants (Phaseolus vulgaris) were performed using field collected A. funzaensis and E. atratus individuals in separate assays. After 5 weeks, the test plants exposed to individuals of both species of leafhoppers showed symptoms, suggesting phytoplasma infection. Phytoplasma groups 16SrI and 16SrVII were detected in the two groups of exposed plants, indicating that A. funzaensis and E. atratus were able to transmit both groups of phytoplasmas. This is the first report of insect vectors for phytoplasmas of group 16SrVII in the world and of 16SrI in South America.     

3种检疫性葡萄黄化植原体的快速检测

 葡萄上的植原体病害由于引起叶片黄化而被称为葡萄黄化病。由于这一病害极为严重,葡萄黄化植原体被列为我国的植物检疫对象。其中,葡萄金黄化植原体(16SrV)、维吉尼亚葡萄黄化植原体(16Sr芋) 和澳大利亚葡萄黄化植原体 (16Sr狱) 是引起葡萄黄化病的主要3 个株系,它们导致的病害症状相似,难以区分。本文进行了3 个株系16S rRNA 基因 DNA 序列比对,而后根据同源性相对低的序列设计了43 条特异性引物、103 对引物对组合,对葡萄黄化植原体3 个株系各自的DNA 及混合DNA 进行PCR 扩增,从中筛选出来特异性较强的8 个引物对组合。这些引物对组合,能够同步、特异、快速地检测3 种葡萄黄化植原体。     

Detection and characterization of a phytoplasma associated with annual blue grass (Poa annua) white leaf disease in southern Italy

A phytoplasma was detected in annual blue grass (Poa annua L. Fienardo), exhibiting white leaf symptoms, that was grown in the fields near Caserta in southern Italy. Based on restriction fragment length polymorphism analysis of PCR-amplified 16S rDNA sequences, the phytoplasma associated with annual blue grass white leaf disease was identified as a new member of phytoplasma 16S rRNA group XI (16SrXI) (type strain, rice yellow dwarf phytoplasma). The annual blue grass white leaf phytoplasma is most closely related to Bermuda grass white leaf phytoplasma found in Asia. Annul blue grass white leaf and Bermuda grass white leaf phytoplasmas were designated as the third subgroup (16SrXI-C) of group XI. This is the first report that a plant pathogenic phytoplasma belonging to group 16SrXI is present on the European continent.     

Seasonal distribution of phytoplasmas in Australian grapevines

The distribution and persistence of phytoplasmas were determined in Australian grapevines. Phytoplasmas could be detected using the polymerase chain reaction (PCR) from shoots, cordons, trunks and roots throughout the year, and phytoplasmas appear to persistently infect Australian grapevines from year to year. Phytoplasmas were not always detected in samples from the same sampling area from one sampling period to the next. Phytoplasma detection by PCR was improved by sampling from shoots, cordons and trunks, especially during October (early spring). The diseases expressed by the 20 grapevines used in the distribution and persistence studies were monitored. Australian grapevine yellows disease (AGY) was expressed by 17/20 grapevines at some time during the study, whilst only 4/20 and 15/20 grapevines expressed restricted growth disease (RG) and late season leaf curl disease (LSLC), respectively. All grapevines with RG and LSLC also had AGY. The three diseases were persistently expressed in some grapevines and remission of disease was observed in others. The results of PCR detection in the same grapevines indicated that phytoplasmas were more frequently detected in AGY-affected grapevines that also expressed RG and LSLC compared with grapevines expressing AGY alone. Phytoplasmas were detected in symptomless plant material but less frequently compared with AGY-affected material.     

Association of phytoplasmas with the decline of European hazel in southern Italy

In the Campania region of southern ltaly. commercial orchards of European hazel ( Corylus avellana ) are severely affected by yellowing and decline. To determine whether phytoplasmas are associated with the disorder, stem samples from diseased trees were examined using polymerase chain reaction assays. No visible products were obtained by amplification of sample DNA with universal and group-specific phytoplasma primers. However, when the products obtained with universal primers were re-amplified with nested primers that were specific for the fruit tree phytoplasmas of the apple proliferation group, most samples tested positively. Restriction site analysis revealed that the trees were infected with the apple proliferation, pear decline, and European stone fruit yellows phytoplasmas in about the same proportion. Some of the trees were doubly infected with one of the fruit tree phytoplasmas and the aster yellows agent. Most of the infected trees were also identified by hybridization of the products obtained in the initial amplification with suitable oligonucleotide probes.     

Molecular characterization of the phytoplasmas associated with toon trees and periwinkle in India

In November 2008 in Himachal Pradesh and Chandigarh regions in India, toon trees and periwinkles were observed to have formed short internodes, small leaves and witches’-broom symptoms, typical of phytoplasma infection. The symptomatic toon and periwinkle samples were tested with universal PCR tests, and the 16S rRNA, rplB-rpsC, secA and secY genes were sequenced. The causal agents belonged to subgroup 16SrI-B of ‘Candidatus Phytoplasma asteris’, based on 16S rDNA, ribosomal protein gene, secA and secY phylogenetic analysis.     

植原体引起雪花木小叶病在中国的首次报道

2022年首次在广州市发现园林植物雪花木小叶病病株, 采用分子生物学技术对其进行植原体的种类鉴定。以雪花木叶片总DNA为模板, 利用植原体16S rRNA通用引物P1/P7进行PCR扩增, 获得广东雪花木小叶病植原体(BLL-GD2022)16S rRNA基因片段(1 811 bp, GenBank登录号为OQ625536)。16S rRNA序列相似性显示, BLL-GD2022与16SrVI组植原体株系的相似性最高, 为97.05%~99.83%, 其中与隶属于16SrVI-D亚组的10个植原体株系相似性为99.21%~99.83%。系统进化分析显示, BLL-GD2022与16SrVI组各植原体株系聚类在一个大分支, 其中与16SrVI-D亚组成员聚类在一个小分支, 亲缘关系最近。基于16S rRNA序列的iPhyClassifier限制性内切酶虚拟RFLP分析表明, BLL-GD2022与16SrVI-D亚组的参考株系Brinjal little leaf phytoplasma (GenBank登录号为X83431)的酶切图谱一致, 相似系数为1.00。基于上述研究结果, 明确广州市雪花木小叶病植原体隶属16SrVI-D亚组成员。本研究首次在园林植物雪花木上检测到植原体, 通过16S rRNA序列分析明确为16SrVI-D亚组成员, 为开展16SrVI-D亚组植原体在蔬菜、花卉和园林植物的发生监测及病害防控提供科学依据。     

Use of terminal restriction fragment length polymorphism (T-RFLP) for identification of phytoplasmas in plants

A terminal restriction fragment analysis (T-RFLP) technique was developed for the simple and rapid detection and diagnosis of phytoplasmas in plants. The selected primers amplified part of the 23S rRNA gene to provide improved resolution between the taxonomic groups compared to conventional restriction enzyme analysis of the 16S rRNA. Using the restriction enzymes Bsh 12361 and Mse I on the PCR products, and fragment analysis in the range 68–640 bp, the technique was tested on 37 isolates from 10 of the 16Sr groups. Distinct and unambiguous T-RFLP profiles were produced for nine of the 10 taxonomic groups, such that almost all isolates within a group shared the same profile and could be distinguished from isolates in other groups. The technique also identified the presence of mixtures of phytoplasmas from different groups in samples. Furthermore, the primers were devised to amplify a terminal restriction fragment (TRF) product of a specific defined size (461 bp) from the host plant chloroplast DNA, so that there was a built-in internal control in the procedure to show that the absence of a phytoplasma peak in a sample was the result of no detectable phytoplasma being present, not the result of PCR inhibition. This method offers the possibility of simultaneously detecting and providing a taxonomic grouping for phytoplasmas in test samples using a single PCR reaction.     

Detection and characterization of phytoplasmas in diseased stone fruits and pear by PCR-RFLP analysis in Turkey

During the late summer-early autumn of 2002, surveys were carried out in Turkey to determine the presence of phytoplasma diseases in fruit trees. Phytoplasmas were detected and characterized by PCR-RFLP analysis and TEM technique in stone fruit and pear trees in the eastern Mediterranean region of the country. Six out of 24 samples, including almond, apricot, peach, pear and plum, gave positive results in PCR assays. RFLP analysis usingSspI andBsaAI enzymes of PCR products obtained with primer pair f01/r01 enabled identification of the phytoplasmas involved in the diseases. Stone fruit trees, including a local apricot variety (‘Sakıt’) and a pear sample, were found to be infected with European stone fruit yellows (ESFY, 16SrX-B) and pear decline (PD, 16SrX-C) phytoplasmas, respectively. This is the first report in Turkey of PD phytoplasma infecting pear and of ESFY phytoplasma infecting almond, apricot, myrobalan plum and peach; ESFY phytoplasma infecting Japanese plum was previously reported. http://www.phytoparasitica.org posting July 21, 2005.     

Characterization of Venturia inaequalis pathogenicity on leaf discs of apple trees

Characterization of pathogenicity on whole plants is required to study host-pathogen interactions between Malus × domestica and Venturia inaequalis. We studied the reliability of an in vitro test of pathogenicity on leaf discs. Three strains of V. inaequalis (races 1, 6 and an English race) were inoculated in vitro onto a range of 16 Malus sp. clones including susceptible and resistant clones. The results were compared to those previously obtained in vivo. Resistant clones contained the main major known genes, i.e. Va, Vb, Vbj, Vf, Vg, Vm and Vr. Scab severity and the sporulation of the fungus were assessed 21 days after the inoculation date. The results indicated that it was possible to reproduce incompatible and compatible situations in vitro. A null severity corresponded to the avirulence of the strain for the clone considered. The resistance given by the Vb, Vbj, Vf, Vg, Vm and Vr genes were expressed in vitro. Only the clone carrying the Va gene and inoculated with the race 6 strain presented a compatible situation which was inconsistent with the observations on the whole plant. Improving this test will facilitate studies on the pathogenicity of V. inaequalis populations in relation to resistance genes of the host expressed in vitro as well as its genetic determinism.     

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.     

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.