Detection and Indentification of European Stone Fruit Yellows and Other Phytoplasmas in Wild Plants in the Surroundings of Apricot Chlorotic Leaf Roll-affected Orchards in Southern France

Between 1994 and 1998 a field study was conducted to identify plant hosts of the European stone fruit yellows (ESFY) phytoplasma in two apricot growing regions in southern and southwestern France where the incidence of apricot chlorotic leaf roll was high. A total of 431 samples from 51 different plant species were tested for the presence of phytoplasmas by PCR using universal and ESFY-specific primers. ESFY phytoplasma was detected in six different wild growing Prunus species exhibiting typical ESFY symptoms as well as in symptomless dog rose bushes (Rosa canina), ash trees (Fraxinus excelsior) and a declining hackberry (Celtis australis). The possible role of these plant species in the spread of ESFY phytoplasma is discussed. PCR-RFLP analysis of ribosomal DNA amplified with the universal primers was carried out to characterize the other phytoplasmas found. Thus, elm yellows phytoplasma, alder yellows phytoplasma and rubus stunt phytoplasma were detected in declining European field elm trees (Ulmus carpinifolia Gled), in declining European alder trees (Alnus glutinosa) and in proliferating Rubus spp. respectively. The presence of rubus stunt phytoplasma in great mallow (Malva sylvestris) and dog rose was demonstrated for the first time. Furthermore, the stolbur phytoplasma was detected in proliferating field bindweed (Convolvulus arvensis) and a previously undescribed phytoplasma type was detected in red dogwood (Cornus sanguinea). According to the 16S rDNA-RFLP pattern this new phytoplasma belongs to the stolbur phytoplasmas group.     

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 .     

Oncopsis alni (Schrank) (Auchenorrhyncha: Cicadellidae) as a Vector of the Alder Yellows Phytoplasma of Alnus glutinosa (L.) Gaertn.

Alder yellows phytoplasma was detected by PCR in Alnus glutinosa trees in the Palatine and Mosel areas of Germany. The restriction profiles obtained by TaqI and AluI digestion of a PCR amplified ribosomal DNA fragment from this phytoplasma and a periwinkle isolate of alder yellows from Italy (ALY) could not be distinguished while elm yellows isolates from Europe and North America led to different fragment patterns. Different restriction profiles for ALY and the German alder phytoplasma were obtained by TruI digestion of a non-ribosomal DNA fragment. Phloem feeding insects were collected from infected alder trees. Phytoplasmas of the elm-yellows group were detected by PCR in psyllids and the leafhopper Oncopsis alni. These pathogens were indistinguishable from the phytoplasma found in alder. Only O. alni was able to transmit the pathogen to healthy alder seedlings. Thus, it is the first insect known to transmit this phytoplasma. This leafhopper could be responsible for the ubiquitous infection of Alnus glutinosa due to its close association with alder and its wide distribution in Europe.     

Macropsis mendax as a vector of elm yellows phytoplasma of Ulmus species

A 3-year study was carried out in north-east Italy, the site of recent elm yellows epidemics, to identify vectors for the elm yellows phytoplasma. Using PCR analysis, Ulmus minor and Ulmus pumila , each with and without symptoms, were positive for the elm yellows phytoplasma. Macropsis mendax , a univoltine and monophagous leafhopper, was shown to be the vector of the elm yellows-associated disease agent. PCR analyses demonstrated that the insect was infected both in natural conditions and in the screenhouse after acquisition-feeding on infected elm plants. Groups of M. mendax , collected from naturally infected elm trees, transmitted elm yellows phytoplasma to elm test plants. In nature, Alnus glutinosa trees affected by alder yellows were found in the surroundings of yellows-affected elm trees; the associated disease agent of alder yellows was transmitted under controlled conditions from alder to elm test plants by grafting.     

Phylogenetic relationships among Flavescence dorée strains and related phytoplasmas determined by heteroduplex mobility assay and sequence of ribosomal and Nonribosomal DNA

Heteroduplex mobility assay (HMA) and DNA sequencing were performed on Flavescence dorée (FD) phytoplasma strains and related phytoplasmas belonging to the elm yellows group. Part of the ribosomal RNA gene operon and a nonribosomal DNA region were utilized for phylogenetic analyses. Two FD strains, FD92 and FD-D, detected in France and Italy, respectively, were identical in both DNA fragments, confirming previous results. Other FD strains were all very similar and most closely resembled ALY, an Italian alder phytoplasma. Phytoplasmas associated with German Palatinate grapevine yellows were shown to form a distinct subcluster, also different from the elm yellows phytoplasma subcluster. Strain disparities revealed by HMA and sequence data were mostly in agreement, highlighting the utility of HMA in differentiation and classification of phytoplasmas belonging to the same ribosomal RNA group.     

Genetic comparison of the peach yellow leaf roll agent with European fruit tree phytoplasmas of the apple proliferation group

Restriction fragment length polymorphism (RFLP) analysis of PCR-amplified ribosomal DNA and Southern blot hybridization using cloned chromosomal DNA fragments from the apple proliferation (AP) phytoplasma as probes were used to investigate the genetic relationship of the California peach yellow leaf roll (PYLR) agent with phytoplasmas causing fruit tree diseases in Europe. This comparison showed that the California PYLR phytoplasma is closely related to apple proliferation (AP), pear decline, and European stone fruit yellows phytoplasmas and that it is a member of the phylogenetic AP group. The PYLR agent could clearly be distinguished from the AP and European stone fruit yellows phytoplasmas by Southern blot hybridization with DNA fragments from the AP phytoplasma and by RFLP analysis of ribosomal DNA employing Ssp I, Bsa AI, and Rsa I restriction endonucleases. However, the PYLR phytoplasma was indistinguishable from the pear decline agent by RFLP analysis of PCR-amplified ribosomal DNA.     

Detection and differentiation of grapevine yellows phytoplasmas belonging to the elm yellows group and to the stolbur subgroup by PCR amplification of non-ribosomal DNA

Primer pairs were designed from a cloned DNA probe of a strain of flavescence dorée (FD) phytoplasma and from a cloned DNA probe of a strain of stolbur phytoplasma. Among an array of reference phytoplasma strains maintained in periwinkle, pair FD9f/r amplified a 1.3 kb DNA fragment only with phytoplasma strains of elm yellows (EY) group, i.e. two strains of FD and two strains of EY. Tru9I restriction analysis of the fragment amplified by FD9f/r revealed a diversity among EY-group phytoplasmas. The FD strains differed from the strains isolated from elm. The profile of the phytoplasmas infecting the grapevine samples from Catalonia and most of the samples from Northern Italy were identical to that of a FD strain. Three other profiles were detected in grapevine from Palatinate, in Germany.The two primer pairs derived from a stolbur strain, STOL4f/r and STOL11f2/r1, specifically amplified a 1.7 kb and a 0.9 kb DNA fragment, respectively, with all strains in the stolbur subgroup. However, the pair STOL4f/r did not recognise strain MOL. Both pairs allowed to detect phytoplasmas in diseased grapevines from France, Italy, Spain and Israel. Attempts to differentiate between phytoplasmas in the stolbur subgroup by restriction analyses failed. The pairs FD9f/r and STOL11f2/r1 could be used in the same reaction (multiplex PCR) to detect EY-group phytoplasmas, stolbur-subgroup phytoplasmas or both phytoplasmas simultaneously when template DNAs were mixed.     

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。     

Pre- and post-embedding immunogold labeling and electron microscopy in plant host tissues of three antigenically unrelated MLOs: primula yellows,tomato big bud and bermudagrass white leaf

Methods are described for pre- and post-embedding immunogold labeling of mycoplasmalike organisms (MLOs) in thin sections of infected plants. Antisera against primula yellows (PY), tomato big bud (TBB) and bermudagrass white leaf (BGWL) MLOs, and a monoclonal antibody (mab) against PY were tested with the three serologically unrelated MLOs. Labeling was specific for each MLO and was localized to the outer surface of the MLOs. The antisera performed well in both pre- and post-embedding experiments; the mab reacted well in pre-embedding conditions but gave no labeling with post-embedding. Glutaraldehyde fixation reduced levels of labeling in post-embedding conditions. The results show that these techniques can be used to differentiate MLOs reliably, and extend the usefulness of electron microscopy in this area.     

Detection of the German grapevine yellows (Vergilbungskrankheit) MLO in grapevine,alternative hosts and a vector by a specific PCR procedure

A polymerase chain reaction procedure was developed which enables specific amplification of a ribosomal sequence from the mycoplasmalike organism (MLO) associated with German grapevine yellows (Vergilbungskrankheit, VK) and stolbur-related diseases of solanaceous plants. Successful amplification from all samples prepared from various cultivars collected in different viticultural areas indicates that the causal agent is a relatively homogeneous organism. Amplification was also achieved with template DNA prepared from naturally infected weeds in vineyards such asConvolvolus arvensis andSolanum nigrum, and from the planthopperHyalesthes obsoletus that was collected in the vineyards. Feeding of insects of this species on grapevine seedlings resulted in the development of typical yellows symptoms by the grapes.H. obsoletus could therefore be identified as a vector of Vergilbungskrankheit.Abbreviations FD Flavescence dorée - GY Grapevine yellows - MLO Mycoplasmalike organism - PCR Polymerase chain reaction - RFLP restriction fragment length polymorphism - VK Vergilbungskrankheit (German grapevine yellows)     

几种植物类菌原体(MLOs)的分子检测及其遗传相关性比较

 以密西根翠菊黄化病MLO 16S rDNA序列为依据,参照有关引物序列,改进合成寡核苷酸R₁和L₁作为引物对,应用聚合酶链式反应(PCR)技术,以甘薯丛枝病(SPWB),泡桐丛枝病(PWB),枣疯病(JWB)和枣疯病长春花(JPWB)罹病植株中提取的DNA为模板,扩增出了1.2 Kb的MLO 16S rDNA片段。该方法所需罹病植株的总DNA量分别为:甘薯丛枝病2×10^-2 ng/μl,泡桐丛枝病0.4×10^-2 ng/μl,枣疯病0.8×10^-2 ng/μl,感染枣疯病的长春花0.3×10^-3 ng/μl。对1.2kb 16S rDNA进行限制性片段长度多态性(RFLP)分析,首次确证枣疯病的罹病植株中存在枣疯病MLO和泡桐丛枝病MLO混合侵染的现象。     

Immunosorbent electron microscopy and gold label antibody decoration of MLOs from crude preparations of infected plants and vector insects

A simple method is given for immunotrapping, gold labelling and electron microscopy of mycoplasmalike organisms (MLOs) from crude preparations of infected plants or insects, enabling MLOs to be confidently distinguished from host materials in negative stain preparations. The appearance of the MLOs is described. MLOs were trapped from extracts of infected periwinkle plants ( Catharanthus roseus ) and infected vector leaf hoppers ( Macrosteles quadripunctulatus ), using electron microscope grids coated with the F(ab)₂ portion of specific rabbit IgGs. The MLOs were then decorated with the intact igG and labelled with goat anti-rabbit IgG conjugated to gold particles 5 or 15 nm in diameter. Preparations were negatively stained in 0.5% ammonium molybdate or left unstained. The MLOs used were European aster yellows (EAY) from plant and vector, and Australian tomato big bud (TBB) from the plant. Preparation time was 4 h; large numbers of MLOs and MLO fragments could be trapped and identified, and EAY could be confidently distinguished from the serologically unrelated TBB. Morphologically, EAY and TBB were indistinguishable, both presenting spheroidal bodies, tubular forms and apparently budding chains of cocci. Bacilliform virus-like particles were sometimes associated with EAY MLOs, especially those from the vector.     

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.     

小麦蓝矮植原体寄主范围的鉴定及RFLP分析

 小麦蓝矮是我国首次报道的小麦植原体病害。采用介体接种植物,症状观察和应用植原体16S rDNA基因通用引物对R16mF2/R16mR1进行PCR扩增,在接种小麦和传毒介体中均扩增出1.4kb的特异片段,鉴定出小麦蓝矮植原体新寄主7种。用巢式PCR方法对小麦蓝矮病田自然发病杂草进行分子检测,从表现症状的10种杂草中均扩增出1.2kb的特异片段。利用6种植原体特异性限制性内切酶对10种杂草的扩增片段进行RFLP(restriction fragment length polymor-phism)分析表明:扩增片段的RFLP图谱与目前已知的16Sr I组翠菊黄化植原体的RFLP图谱相近。鉴定出小麦蓝矮植原体田间自然新寄主10种。     

Characterization and classification of phytoplasmas from wild and cultivated plants by RFLP and sequence analysis of ribosomal DNA

Restriction fragment length polymorphism and sequence analysis of PCR-amplified ribosomal DNA were used to identify and classify phytoplasmas associated with diseases of various wild and cultivated plants. The diseases examined were either not known before or the presumable causal agents were not yet identified and characterized or were only known from other geographic areas. New diseases examined were those causing virescence and phyllody of Bunias orientalis and Cardaria draba. Both were associated with strains of the aster yellows phytoplasma. The same type of aster yellows phytoplasma was also found to be associated with yellows and phyllody diseases of Portulaca oleracea, Stellaria media, Daucus carota ssp. sativus, and Cyclamen persicum. In German and French DNA samples from diseased Trifolium repens, the clover phyllody phytoplasma was identified, which could clearly be distinguished from other phytoplasmas of the aster yellows group. Strains of the stolbur phytoplasma were detected in big bud-affected tomatoes and almost exclusively in Convolvulus arvensis. In Cirsium arvense and Picris echioides two distinct phytoplasmas were identified which showed relationship to the sugarcane white leaf phytoplasma group but may represent a new group or subgroup. In Conyza (syn.: Erigeron) canadensis a phytoplasma of the X-disease group was detected. A strain from Gossypium hirsutum showed the same restriction profiles as the faba bean phyllody phytoplasma.     

DNA probes and PCR primers for the detection of a phytoplasma associated with peanut witches'-broom

EcoRI restriction fragments of genomic DNA from the phytoplasma associated with peanut witches'-broom (PNWB) were cloned in plasmid pGEM-3Zf(+). Cloned inserts from seven PNWB-phytoplasma-specific recombinant plasmids and two subcloned plasmids were excised with restriction enzymes, labeled with digoxigenin, and used as probes. Probe PNWB281 and its derivative subclones PNWB281-4 and PNWB281-5 hybridized with DNA from PNWB-phytoplasma infected peanut and periwinkle specifically but not with DNA from healthy plants or plants infected with phytoplasmas associated with sweetpotato witches'-broom (SPWB), loofah, Ipomoea obscura, and paulownia witches'-broom, elm and aster yellows, rice yellow dwarf, and bamboo little leaf disease. Six other probes hybridized with DNA derived from PNWB and SPWB-phytoplasma-affected periwinkle but not with DNA from healthy plants or plants infected with other phytoplasmas mentioned. In Southern hybridizations, four of the nine cloned and subcloned probes could differentiate the PNWB-phytoplasma from SPWB-phytoplasma. Three primer pairs for PCR were synthesized according to the partial sequences at both ends of the cloned inserts and were able to distinguish PNWB-phytoplasma from SPWB-phytoplasma by using PCR for the first time. A minimum of 1 pg and 10 pg of total DNA from diseased periwinkle and peanut, respectively, was sufficient to amplify the specific PNWB-phytoplasma PCR fragments, allowing the detection of PNWB-phytoplasma DNA from healthy-looking periwinkle plants two weeks after graft inoculation.     

人工培养液在植原体昆虫介体筛选中的适用性

研究了一种人工培养液对各种常见的昆虫(主要是叶蝉)的亲和性和适用性.结果表明,该人工培养液适于本试验中大多数昆虫的人工饲养.用此方法,悬钩子广头叶蝉Macropsis.ftscula Zetterstedt和桤树广头叶蝉Oncopsis alniSchrank分别被再次确认为悬钩子矮化植原体和桤树黄化植原体的传播介体;田旋花麦蜡蝉Hyalesthes obsoletus Signoret再次被确认为葡萄黄化(stolbur)植原体的传播介体.此前,上述三种叶蝉已被传统的人工接种方法鉴定为相应植原体的传播介体.危害桤树的河谷树叶蝉Allygus modestus Scott尽管虫体DNA检测结果经常为阳性,但迄今其人工培养液的检测结果都是阴性,因此,我们认为河谷树叶蝉不是桤树黄化植原体的传播介体.Eppendorf管人工培养液饲养法不仅适用于潜在的植原体介体昆虫的筛选鉴定,而且可用于介体昆虫的生物防治研究.此外,本研究首次发现自然感染了葡萄上的一种被德国人称为"Vergi-lungskrankheit"植原体(AY组)的草地脊冠叶蝉Aprodes makarovi Zachvatkin.     

Standard and Swedish variant types of the hybrid alder Phytophthora attacking alder in Hungary

A new Phytophthora disease of common alder (Alnus glutinosa) similar to that previously reported in several countries in Europe has been observed in Hungary. Based on these earlier studies, the alder Phytophthora was considered likely to be a hybrid between P cambivora and a P fragariae-like species: across Europe a range of new alder Phytophthora is spreading that comprise a range of heteroploid hybrids including a 'standard' hybrid type and several other hybrid types termed 'variants'. Phenotypic and molecular features of the pathogen in Hungary were characterised and compared with isolates from elsewhere. The morphologies of five isolates from one region (Hévíz) resembled the common, 'standard' type, whereas the three isolates from another region (Hanság) exhibited traits similar to those of one of the 'variant' types, ie the Swedish 'variant'. Molecular markers of these two groups of Hungarian isolates also represented a good fit to those of the standard type and the Swedish variant, respectively. Isozyme patterns and profiles of restriction fragments of the entire internal transcribed spacer (ITS) region or mitochondrial DNAs and of RAPD-PCR products did not differ within a group, but distinct polymorphisms were exhibited between the two groups of isolates. Southern analysis of random amplified polymorphic DNA (RAPD) revealed the homologous nature of co-migrating bands of P cambivora and the isolates of alder Phytophthora. Furthermore, restriction fragment profiles of the ITS region of ribosomal DNAs and the mtDNAs were consistent with reported biparental origin of alder Phytophthora. The hybrid status of these continuously evolving pathogens raises many issues and challenges concerning efficient control measures.     

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.     

Monoclonal antibody for the detection and identification of a phytoplasma associated with rice yellow dwarf

One stable hybridoma clone, 247B11, secreting specific monoclonal antibody (MA) against the mycoplasmalike organism (MLO), newly be termed phytoplasma, associated with rice yellow dwarf (RYD) was produced by employing an immunization scheme for inducing the immunological tolerance of mice to rice antigens prior to the administration of RYD-phytoplasma immunogens. Neonatal BALB/c mice were first injected with nontarget rice antigens present in the immunogen preparation and were immunized intrasplenically with RYD-phytoplasmaenriched antigens prepared by Percoll density-gradient fraction 6 wk later. The MA was of the IgG1 class. With this MA, RYD-phytoplasma in diseased rice was specifically detected by indirect enzyme-linked immunosorbent assay (ELISA), immunofluorescent staining and tissue-blotting techniques. Antibody titer determined by indirect ELISA for hybridoma-culture supernatant was 5120. The antibody recognized two polypeptides, 16 kDa and 41 kDa of RYD-phytoplasma determined by western blotting. RYD-phytoplasma was differentiated serologically from the phytoplasmas associated with sweetpotato, peanut, loofah, paulownia, andIpomoea obscura witches' broom, aster yellows (NJ strain), elm yellows, and sugarcane white leaf both in indirect ELISA and immunofluorescent staining.