Distinctions between phytoplasmas at the subgroup level detected by heteroduplex mobility assay

A total of 62 phytoplasma isolates were collected from North America, Europe and Asia and analysed by heteroduplex mobility assay (HMA) of the 16/23S spacer region amplified by the polymerase chain reaction. The results revealed wide genetic diversity among the phytoplasmas studied and a number of new phytoplasma strains were identified from known or new plant hosts in Alberta, Canada. Two distinctive subgroups were revealed by HMA in phytoplasmas associated with canola yellows, Chinese aster yellows, dandelion yellows and monarda yellows. In Alberta, two subgroups of the aster yellows group of phytoplasmas, I-A and I-B, were prevalent in naturally infected field crops and ornamentals in open gardens. The results indicated that HMA is a simple, but rapid and accurate, alternative method for the detection and estimation of genetic divergence of phytoplasmas when finer molecular characterization of phytoplasmas is required at the subgroup level.     

Identification of a phytoplasma causing yellows of Monarda

Monarda yellows occurring in southern Alberta was found to be associated with a phytoplasma. Using two pairs of universal primers, 16S ribosomal DNA fragments (about 1.5 and 1.2 kb) were amplified separately by polymerase chain reaction (PCR) from DNA samples that had been extracted from infected monarda. No such DNA bands were observed using DNA samples from uninfected monarda. The DNA fragment (1.2 kb) amplified by nested-PCR was analysed and compared with western aster yellows (AY27, Canada), eastern aster yellows (EAY, USA), French hydrangea aster yellows (AYHF), Belgium hydrangea aster yellows (AYHB), clover proliferation (CP, Canada) and potato witches'-broom (PWB, Canada) by means of restriction fragment length polymorphism (RFLP) using endonucleases Alu I, Mse I, Hpa II, Sau 3AI, Kpn I and Rsa I. The results showed that monarda yellows phytoplasma belongs to the aster yellows subclade and is different from CP and PWB. This is the first report of aster yellows phytoplasma infecting monarda.     

我国几种植物植原体的快速分子鉴别与鉴定的研究

 选用桑萎缩病(Mulberry dwarf,MD)、枣疯病(Jujube witches'-broom,JWB)、酸枣丛枝病(Wild jujube witches'-broom,WJWB)、泡桐丛枝病(Paulownia witches'-broom,PaWB)和苦楝丛枝病(Chinaberry tree witches'-broom,CWB)5种不同植物植原体和来源于3个不同地区PaWB和JWB材料进行16S rDNA和23S rDNA PCR扩增、异源双链迁移率分析(HMA)、PCR产物的RFLP分析和16S rDNA的克隆和测序等比较研究,建立了一种快速确定未知植原体种类和分类地位的分子鉴别与鉴定优化程序;并可对田间采集的各种植物植原体样品进行快速鉴定和鉴别。16S rDNA PCR产物HMA分析结果显示,JWB与CWB、MD和PaWB皆可形成明显的异源杂交双链;而CWB、MD和PaWB植原体之间未能形成异源双链。JWB和PaWB不同地区样品之间、JWB和WJWB之间也未发现异源杂交双链的形成。而23S rDNA PCR产物HMA分析则可以将MD与PaWB区分开。进一步对未知分类地位的CWB序列测定及与其它植原体16S rDNA的RFLP和同源性比较结果显示,CWB与PaWB同源性为99.5%,其中与MD的同源性高达99.7%,因而应将CWB归为翠菊黄花组16Sr I-B,16Sr I-B (rp-B)。     

Differential detection and genetic relatedness of phytoplasmas in papaya

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

Comparison of phytoplasmas infecting winter oilseed rape in the Czech Republic with Italian Brassica phytoplasmas and their relationship to the aster yellows group

Winter oilseed rape grown in several areas in South Bohemia showed symptoms of stunting, leaf reddening and extensive malformation of floral parts. Phytoplasmas were consistently observed by using electron microscopy only in phloem tissue of symptomatic plants. DNA isolated from infected and healthy control plants was used in PCR experiments. Primer pairs R16F2/R2, P1/P7 and rpF2/R2, amplifying, respectively, 16S rDNA, 16S rDNA plus spacer region and the beginning of the 23S and ribosomal protein gene L22 specific for phytoplasmas, were used. According to RFLP and sequence analyses of PCR products, the phytoplasma from rape was classified in the aster yellows phytoplasma group, subgroup 16SrI-B. The PCR products from the Czech phytoplasma-infected rape also had RFLP profiles identical to those of phytoplasma strains from Italian Brassica . This first molecular characterization of phytoplasmas infecting rape compared with strains from Brassica does not, however, clearly indicate differences among isolates of the same 16SrI-B subgroup. Further studies on other chromosomal DNA portions could help the research on host specificity or on geographical distribution of these phytoplasmas.     

Association of 'Candidatus Phytoplasma australiense' with green petal and lethal yellows diseases in strawberry

The identity of phytoplasmas detected in strawberry plants with green petal (SGP) and lethal yellows (SLY) diseases was determined by RFLP analysis of the 16S rRNA gene and adjacent spacer region (SR). RFLP and sequence comparisons indicated that the phytoplasmas associated with SGP and SLY were indistinguishable and were most closely related to ' Candidatus Phytoplasma australiense', the phytoplasma associated with Australian grapevine yellows, papaya dieback and Phormium yellow leaf diseases. This taxon lies within the aster yellows strain cluster. Primers based on the phytoplasma tuf gene, which amplify only members of the AY strain cluster, amplified a DNA product from the SGP and SLY phytoplasmas. Primers deduced from the 16S rRNA/SR of P. australiense that amplify only members of this taxon amplified rDNA sequences from the SGP and SLY phytoplasmas. Primers that selectively amplify members of the faba bean phyllody (FBP) phytoplasma group, the most commonly occurring phytoplasma group in Australia, did not amplify rDNA from the SGP and SLY phytoplasmas.     

广东桉树黄化(丛枝)病植原体分子鉴定与检测

从表现黄化(丛枝)症状的桉树上采集病叶,抽提主脉总DNA,采用植原体通用引物与巢式引物进行PCR和巢式PCR扩增,对扩增产物进行克隆和序列测定,获得了植原体的近全长16S rRNA基因及部分16～23S rRNA基因间隔区序列.序列分析揭示,所获得的序列与已知植原体基因组相应区段的序列高度同源,与柳叶菜变叶植原体(epilobium phyllody)和白腊树丛枝植原体(ash witches'-broom)相应序列(GenBank登录号:AY101386和AY566302)同源率为99.9%,与白腊树黄化植原体(aster yellows BD2)相应序列和番茄巨芽植原体(tomato big bud)相应序列同源率分别为99.6%和99.3%.该序列构建的系统进化树表明,引起我国广州地区桉树黄化(丛枝)病的植原体属于16SrI组(即翠菊黄化组),将其暂命名为桉树黄化(丛枝)植原体广东株系(Eucalyp-tus yellowing and witches'-broom phytoplasma strain Guangdong,EYWB-Gd).建立了桉树植原体巢式PCR检测方法,对疑似病样及桉树组培苗进行了检测,多数疑似病样检测结果为阳性,供试的10株组培苗未发现阳性样品.     

Electron microscopy and molecular identification of phytoplasmas associated with strawberry green petals in the Czech Republic

The presence of phytoplasma inFragaria ananassa x Duch cv Senga Sengana showing strawberry green petals symptoms was observed by electron microscopy of phloem tissue. No phytoplasmas were found in asymptomatic strawberry plants used as controls. Nucleic acids extracted from these plants were used in nested-PCR assays with primers amplifying 16S rRNA sequences specifie for phytoplasmas. Bands of 1.2 kb were obtained and the subsequent nested-PCR with specific primers and RFLP analyses allowed to classify the detected phytoplasmas in the aster yellows group (16SrI). They belonged to the subgroup I-C of which type strain is clover phyllody phytoplasma.     

The occurrence of two phytoplasmas associated with stunted Rubus species in the UK

Polymerase chain reaction using universal primers to sequences in the 16S rRNA gene, and group-specific primers to sequences in the 16S/23S spacer region, revealed two distinct phytoplasmas occurring in Rubus plants showing symptoms of rubus stunt. One phytoplasma appeared similar to phytoplasmas in the elm yellows group; the other appeared to fall into the X disease group. This finding was confirmed by RFLP analysis of PCR products. This is the first identification of phytoplasmas from either of these groups occurring in the UK, and the first report of a phytoplasma belonging to the X disease group in Rubus .     

紫花苜蓿丛枝病植原体的分子检测及鉴定

 利用植原体16S rRNA基因通用引物对云南昆明发生的苜蓿丛枝病感病植株总DNA进行巢式PCR扩增,得到1.2kb的特异片段,从分子水平证实了苜蓿丛枝病的病原是植原体。从PCR产物的RFLP酶切图谱可看出,该植原体株系的酶切图谱与马里兰翠菊黄化植原体(AY1)相同。对扩增片段进行克隆及序列测定后,利用最小进化法做Bootstrap验证的系统进化树,表明苜蓿丛枝病植原体为Candidatus Phytoplasma asteris成员之一,与植原体16SrI-B亚组成员关系密切。     

Molecular and symptom analyses of phytoplasma strains from lettuce reveal a diverse population

ABSTRACT Epidemics of aster yellows in lettuce in Ohio are caused by at least seven distinct phytoplasma strains in the aster yellows (AY) group. Five of the strains are newly reported: AY-BW, AY-WB, AY-BD3, AY-SS, and AY-SG. All seven strains were characterized based on symptoms in aster and lettuce, and by polymerase chain reaction (PCR). Strain AY-BD2 (formerly 'Bolt') causes yellowing and leaf distortion in lettuce and bolting in aster, whereas strain AY-S (formerly 'Severe') causes stunting, leaf clustering, and phyllody. Strain AY-WB causes yellowing and wilting in lettuce and witches'-broom in aster. Strain AY-SG induces horizontal growth in lettuce and aster plants. Strain AY-BW causes chlorosis of emerging leaves and abnormally upright growth of leaf petioles. AY-SS causes symptoms similar to those caused by AY-S but has a different PCR-restriction fragment length polymorphism (RFLP) banding pattern. Strains AY-BD2 and AY-BD-3 cause mild leaf and stem distortion in lettuce but are differentiated by PCR-RFLP. All phytoplasma strains collected from lettuce in Ohio belong to the 16SrI group. AY-WB belongs to the 16SrI-A subgroup and the other six belong to the 16SrI-B subgroup. Five of the seven strains were distinguished from each other by primer typing. The results of phylogenetic analyses of sequences of the 16S rRNA genes were basically consistent with the classification based on PCR-RFLP, in which AY-WB clustered with phytoplasmas of the 16rIA subgroup and the other Ohio lettuce strains clustered with phytoplasmas in the 16SrI-B subgroup.     

榆树黄化病植原体的分子检测与鉴定

 利用植原体16SrRNA基因的通用引物R16rrLF2/R16mR1和R16F2n/R16R2对山东泰山上发生的榆树(Ulmus parvifolia)黄化病感病植株总DNA进行巢式PCR扩增,得到了约1.2kb的特异性片段,从分子水平证实了榆树黄化病的病原(EY-China)为植原体。将扩增到的片段测序,并进行一致性和系统进化树分析。结果表明,该分离物属于植原体榆树黄化组(Candidatus Phytoplasma ulmi),与该组成员16SrRNA序列的一致性均在98.2%以上,其中与16SrV-B亚组中的纸桑丛枝(Paper mulberry wiches'-broom)和枣疯病(Jujube witches'-broom)植原体一致性最高,达到99.4%,在系统进化树中与该亚组成员聚类到同一个分支,说明该分离物属于植原体16SrV-B亚组。本研究首次对在中国引致榆树黄化病的植原体进行了分子检测,并通过核酸序列分析将其鉴定到亚组水平。     

臭矢菜丛枝病植原体的分子鉴定研究

 本实验采用DAPI荧光显微镜、PCR、克隆和测序等技术,对海南臭矢菜丛枝病样进行了检测和鉴定。以染病臭矢菜总DNA为模板应用3对植原体特异性引物进行PCR扩增,获得PCR产物为16S rDNA(1 430 bp)、16S-23S rDNA(358bp)、rp DNA(1 294 bp)。应用DNA回收试剂盒获得了3个PCR扩增片断的纯化产物,并克隆到DH5α大肠杆菌中测序。应用DNAMAN和MEGA软件对获得的序列与NCBI数据库中植原体序列进行同源性分析和构建系统发育树。结果显示臭矢菜丛枝病植原体与花生丛枝病植原体序列同源性最高,16S rDNA的序列同源性为99.9%,16S-23S rDNA高达100%,rp为99.7%,因而将臭矢菜丛枝病植原体归为花生丛枝组(16SrⅡ),根据16S rDNA的RFLP分析,将其归为16SrⅡ-A亚组。     

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

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

Molecular identification of a phytoplasma associated with Russian olive witches’ broom in Iran

Russian olive trees (Elaeagnus angustifolia) showing witches’ broom symptoms typical of phytoplasma infection were observed in the Urmia region of Iran. A phytoplasma named Russian olive witches’ broom phytoplasma (ROWBp-U) was detected from all symptomatic samples by amplification of the 16S rRNA gene and 16S/23S rDNA spacer region using the polymerase chain reaction (PCR) which gave a product of expected length. DNA from symptomless plants used as a negative control yielded no product. The sequence of the 16S rRNA gene and 16S/23S rDNA spacer region of ROWBp-U showed 99% similarity with the homologous genes of members of the aster yellows group. We also detected a phytoplasma in neighboring alfalfa plants (AlWBp-U) showing severe witches’ broom symptoms. An 1107 bp PCR product from the 16S rRNA gene showed 99% homology with the corresponding product in ROWBp-U, suggesting the presence of the same phytoplasma actively vectored in the area. Further observations showed that Russian olive trees with typical ROWB symptoms were present in an orchard near Tehran which is located over 530 km south-east of the original Urmia site. The corresponding sequence of this phytoplasma (ROWBp-T) showed 99% homology to that of the ROWBp-U. A sequence homology study based on the 16S rRNA gene and 16S/23S rDNA spacer region of ROWBp-U and other phytoplasmas showed that ROWBp-U is most closely related to the 16SrI group. To our knowledge, this is the first report of a phytoplasma infection in a member of the Elaeagnaceae.     

Detection and identification of phytoplasmas in yellows-diseased weeds in Italy

Yellows-diseased plants of Crepis setosa (hawksbeard), Knautia arvensis (field scabious), Convolvulus arvensis (field bindweed), Picris echioides (bristly oxtongue), Echium vulgare (blueweed) and Calendula officinalis (pot marigold) collected in central and southern Italy were examined for phytoplasma infection by means of polymerase chain reaction (PCR) technology using universal phytoplasma primers directed to ribosomal sequences. The detected phytoplasmas were characterized and differentiated using restriction fragment length polymorphism analysis of PCR-amplified DNA. The phytoplasma detected in diseased pot marigold plants was identified as a member of the aster yellows group and proved indistinguishable from a strain of the American aster yellows phytoplasma. The phytoplasma identified in diseased field bindweed plants is a putative new type of the stolbur group that differed from the typical stolbur phytoplasma. Phytoplasmas detected in diseased hawksbeard, blueweed and field scabious plants are all putative new members of the sugarcane white leaf group while the phytoplasma detected in diseased bristly oxtongue plants represents a new member of the faba bean phyllody group. For hawksbeard and field scabious this is the first report on the occurrence of phytoplasma diseases, whereas phytoplasmas infecting bristly oxtongue and blueweed have never been characterized before.     

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

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

Development and evaluation of a one‐hour DNA extraction and loop‐mediated isothermal amplification assay for rapid detection of phytoplasmas

A rapid DNA extraction and loop‐mediated isothermal amplification (LAMP) procedure was developed and evaluated for the detection of two specific groups of phytoplasmas from infected plant material. Primers based upon the 16–23S intergenic spacer (IGS) region were evaluated in LAMP assays for amplification of group 16SrI (aster yellows group) and group 16SrXXII (Cape St Paul wilt group) phytoplasma strains. DNA could be extracted from leaf material (16SrI phytoplasmas) or coconut trunk borings (16SrXXII phytoplasmas) onto the membranes of lateral flow devices, and small sections of these membranes were then added directly into the LAMP reaction mixture and incubated for 45 min at 65°C. Positive reactions were detected through the hydroxyl napthol blue colorimetric assay within 1 h of the start of DNA extraction, and were confirmed by subsequent agarose gel electrophoresis of the LAMP products. The level of detection was comparable to that obtained by nested PCR using conventional 16S rDNA phytoplasma‐specific primers. Furthermore, the assays were specific for the phytoplasmas they were designed to detect – the 16SrI assay only detected 16SrI phytoplasmas and not those from any other phylogenetic groups, whilst the 16SrXXII assay only detected 16SrXXII phytoplasmas. The DNA extractions and LAMP assay are easy to perform, requiring minimal equipment, and may therefore form the basis of a rapid and reliable field‐detection system for phytoplasmas.     

An Antibody Against the SecA Membrane Protein of One Phytoplasma Reacts with Those of Phylogenetically Different Phytoplasmas

ABSTRACT Antisera raised against phloem-limited phytoplasmas generally react only with the phytoplasma strain used to produce the antigen. There is a need for an antiserum that reacts with a variety of phytoplasmas. Here, we show that an antiserum raised against the SecA membrane protein of onion yellows phytoplasma, which belongs to the aster yellows 16S-group, detected eight phytoplasma strains from four distinct 16S-groups (aster yellows, western X, rice yellow dwarf, and elm yellows). In immunoblots, approximately 96-kDa SecA protein was detected in plants infected with each of the eight phytoplasmas. Immunohistochemical staining of thin sections prepared from infected plants was localized in phloem tissues. This antiserum should be useful in the detection and histopathological analysis of a wide range of phytoplasmas.     

Phylogenetic analysis of elongation factor Tu gene of phytoplasmas from Japan

The elongation factor Tu (tuf) gene from nine Japan phytoplasma isolates was amplified with the polymerase chain reaction, and the DNA sequences of the tuf gene were determined. The tuf gene from 14 phytoplasma isolates, including reference isolates and other bacteria, were phylogenetically analyzed. A nucleotide sequence of the tuf gene among seven aster yellows group (16Sr I-B and I-D) phytoplasmas had 97%–100% similarity, and the tuf gene of two phytoplasmas of the X-disease group (16Sr III-B) had 99% similarity. The tuf genes had lower homology than did the 16S rRNA gene in the phytoplasma groups. A phylogenetic tree of amino acid sequences of the tuf gene was nearly equal to that of the 16S rRNA gene but differed somewhat from the tree based on the 16S rRNA gene in that paulownia witches broom (PaW: 16Sr I-D) and American aster yellows (AAY: 16Sr I-B) were in a subclade.The nucleotide sequence data reported are available in the DDBJ/EMBL/GenBank databases under the accession numbers AB095495, AB095667, AB095668, AB095669, AB095670, AB095671, AB095672, AB095673 and AB095674