山东省枣疯病植原体的鉴定及分子变异分析

 本研究对山东省11个地区的枣疯病样品进行了鉴定和分子变异分析。以样品总DNA为模板,经扩增和序列测定,分别得到16S rRNA (1 432 bp)、核糖体蛋白基因rp (1 196 bp)、转运蛋白基因secA (836 bp) 和secY (1 421 bp) 的序列,secA基因序列是首次从枣疯病植原体中扩增获得。对获得的序列与NCBI数据库中相关植原体序列进行聚类和核苷酸变异分析,结果显示山东省枣疯病植原体属于16SrⅤ-B、rpⅤ-C、secYⅤ-C亚组,相对于16S rRNA基因,rp,secA和secY变异更大,非同义突变更多,更利于对国内不同来源的枣疯病植原体的精细系统进化分析。     

云南花生丛枝植原体16S rRNA和核糖体蛋白基因序列分析

 利用植原体16S rRNA基因及核糖体蛋白基因(ribosomal protein, rp)通用引物对发生在云南元谋的花生丛枝病病株DNA进行PCR扩增,并对扩增片段进行序列测定。扩增获得的云南元谋花生丛枝植原体(PnWB-YNym)16S rDNA、16S-23S rDNA和23S DNA片段总长1 806 bp,rp基因扩增片段长1 171 bp。云南株系与来源于台湾和海南的花生丛枝植原体均有较高同源性。比较16S rDNA片段,发现云南株系在5个位点上与来自台湾或海南的株系存在碱基差异,其中有1个位点的差异是云南元谋株系特异的;再分别比较核糖体蛋白rplV-rpsC 2个基因所编码的氨基酸序列,发现云南株系rpsC编码的第194位氨基酸与台湾和海南的株系存在差异。经16S rDNA片段系统进化及iPhyClassifier在线分析,表明PnWB-YNym在分类上属于16SrII-A亚组成员,与候选种‘Candidatus Phytoplasma australasiae’相关;基于rp基因构建的系统进化树表明,PnWB-YNym与16SrII-A亚组各成员聚为同一亚进化支(iii)。     

海南省木豆丛枝病植原体的分子检测及鉴定

 利用植原体通用引物R16mF2/R16mR1和rp (Ⅱ) F1/rp (Ⅱ) R1对海南木豆丛枝病植原体16S rDNA和部分核糖体蛋白(ribosomal protein,rp)基因序列进行PCR扩增、克隆和测序。获得海南木豆丛枝病植原体16S rDNA基因片段为1430bp,rp基因片段为1170bp。核苷酸同源性比较和系统进化树构建表明,引起海南木豆丛枝病的植原体应属于16SrⅡ组中的亚组ⅲ。本研究首次从分子水平确定了引起我国海南木豆丛枝病的病原物为植原体,明确了其分类地位,为该病害流行学研究和防治提供了理论依据。     

菊花绿变病植原体在中国的发生及分子鉴定

对内蒙古农业大学校园内表现花器绿变症状的菊花样品进行采集和DNA提取,应用植原体16S rRNA基因和rp基因的引物进行巢式PCR扩增,从感病样品中分别扩增得到了长度均约为1.2 kb的片段。序列一致性分析表明,菊花绿变植原体16S rRNA基因与翠菊黄化植原体匈牙利风信子株系(GenBank登录号MN080271)、印度玉米株系(KY565571)、印度繁缕株系(KC623537)和印度马铃薯株系(KC312703)的核酸一致性最高,为99.9%,rp基因序列与翠菊黄化植原体立陶宛洋葱株系(GU228514)的核酸一致性最高,为99.8%。基于16S rRNA基因和rp基因构建系统进化树时发现,菊花绿变植原体均与16SrI-B亚组成员聚为一起。16S rRNA基因相似性系数分析表明,菊花绿变植原体与洋葱黄化植原体(AP006628)的相似性系数最高为1.00,洋葱黄化植原体(AP006628)在分类上属于16SrI-B亚组。因此,我们可以确定该菊花绿变植原体属于16SrI-B亚组。这是我国首次报道菊花绿变病的发生。     

宁夏马铃薯僵顶植原体的分子鉴定

通过透射电子显微镜,在从宁夏回族自治区固原市彭阳县红河镇采集的表现叶片上卷、红叶、气生薯症状的马铃薯样品叶脉韧皮部筛管细胞内观察到大量直径为500~700 nm的球形植原体粒子。以提取的感病和健康马铃薯叶片总DNA为模板,应用植原体16S rRNA基因和rp基因通用引物进行PCR扩增,从感病样品中扩增得到了长度均约为1.2 kb的片段。对获得基因核酸一致性比较分析表明,马铃薯僵顶植原体宁夏株系16S rRNA基因与‘Candidatus Phytoplasma fragariae’槭树株系(MK501642)16S rRNA基因核酸一致性最高,为99.7%,rp基因与‘Ca.P.fragariae’云南马铃薯YN-2G株系(KJ144889)rp基因核酸一致性最高,为100%;基于16S rRNA基因和rp基因构建系统进化树发现,马铃薯僵顶植原体宁夏株系与16SrⅫ-E亚组成员聚在一起。基于透射电镜观察和基因序列比较分析,证明宁夏发生的马铃薯僵顶病与植原体侵染相关,该植原体在分类地位上属于植原体16SrⅫ-E亚组。     

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。     

广东番茄巨芽病植原体的分子鉴定

2022年, 对在广东省湛江市廉江市田间发现的疑似番茄巨芽病病株, 利用分子生物学方法对其相关植原体进行了鉴定。以番茄病株叶片总DNA为模板, 利用植原体16S rRNA基因通用引物R16mF2/R16mR1进行PCR扩增, 获得了广东番茄巨芽病植原体(TBB-GD-2022)16S rRNA基因片段(1 430 bp, GenBank登录号为ON102780)。16S rRNA基因序列相似性分析显示, TBB-GD-2022与16SrⅡ组植原体菌株的相似性较高, 为96.82%~100%, 其中与隶属于16SrⅡ-V亚组的6个植原体株系相似性为100%。系统进化分析显示, TBB-GD-2022与16SrⅡ组各植原体株系聚类在一个大分支, 并与16SrⅡ-V亚组成员聚类在一个小分支, 亲缘关系较近。16S rRNA 基因相似系数分析表明, TBB-GD-2022与16SrⅡ-V亚组的参照株系‘Praxelis clematidea’ phyllody phytoplasma (GenBank登录号:KY568717) 的相似系数为1.00。上述研究结果表明, 广东番茄巨芽病植原体隶属16SrⅡ-V亚组成员。本文首次报道在广东发现番茄巨芽病, 通过其16S rRNA序列分析进一步确定了其相关植原体的分类地位, 为该病害的防控提供了科学依据。     

广东花生丛枝病植原体的分子鉴定

2020年在广东省湛江市遂溪县田间发现表现明显丛枝?小叶, 类似植原体感染症状的花生病株?本研究利用分子生物学技术对其病原进行鉴定?以花生病叶的总DNA为模板, 利用植原体16S rRNA和SecY基因通用引物进行PCR扩增, 获得广东花生丛枝病植原体(PnWB-GDSX-2020)16S rRNA基因片段(1 430 bp, GenBank登录号为MZ427281)和SecY基因片段(1 709 bp, GenBank登录号为MZ437794)?序列一致性和系统进化分析显示, PnWB-GDSX-2020的16S rRNA序列与16SrⅡ-A?16SrⅡ-D和16SrⅡ-V亚组植原体一致性最高, 亲缘关系最近; 进一步利用iPhyClassifier对16S rRNA序列进行在线虚拟RFLP分析, 结果显示, PnWB-GDSX-2020的虚拟RFLP 图谱与16SrⅡ-V亚组的参照株系‘Praxelis clematidea’ phyllody phytoplasma (GenBank登录号:KY568717) 酶切图谱一致, 相似系数为1.00?因此, PnWB-GDSX-2020属于16SrⅡ-V亚组成员?所获得的PnWB-GDSX-2020 Sec Y基因序列与花生丛枝植原体的一致性最高, 亲缘关系最近?本文确定了广东花生丛枝病相关植原体的分类地位, 为当地病害诊断?检测以及防控提供科学依据?     

云南泡桐丛枝病植原体核糖体蛋白基因片段序列分析

 应用植原体核糖体蛋白基因通用引物对rpF1/rpR1,对采自云南省曲靖市的泡桐丛枝病植原体DNA (PaWB-QJ)进行PCR扩增,得到1.3 kb的特异片段,证明此病株中存在植原体。将此片段与pGEM-T Easy载体连接并转化大肠杆菌JM109感受态细胞,进行PCR鉴定、核糖体蛋白基因部分核苷酸序列测定及分析。结果表明,该株系(PaWB-QJ)核糖体蛋白基因片段长1 244 bp,包含rps19、rpl22和rps3基因。对PaWB-QJ株系的核糖体蛋白基因序列的同源性比较结果显示与16S rI-B亚组的翠菊黄化(Aster yellows,AY)、长春花黄化(Periwinkle yellows,PY)和泡桐丛枝德国株系(Paulownia witches'-broom,PaWB-German)的亲缘关系最近,达到99.0%以上,而与其它组中的株系明显低于97.0%,所以认为该植原体株系属于翠菊黄化组B亚组(16SrI-B)。     

卵叶山蚂蝗丛枝植原体的分子鉴定

2016年在生长于海南省澄迈县的卵叶山蚂蝗上发现了丛枝、小叶等疑似植原体感染症状。利用植原体16S rRNA基因的通用引物R16mF2/R16mR1,对卵叶山蚂蝗丛枝样品进行了PCR检测,并对检测到的植原体16S rRNA基因片段(1.4 kb)进行克隆测序、序列比对、虚拟限制性片段长度多态性分析和系统进化树构建分析。结果表明,卵叶山蚂蝗丛枝植原体(beggarweed witches'-broom phytoplasma,MK956144)为来檬植原体(Candidatus Phytoplasma aurantifolia,U15442)的相关株系,属于花生丛枝植原体组A亚组(16SrII-A),这是首次发现植原体感染卵叶山蚂蝗的报道。     

棣棠丛枝病相关植原体的分子鉴定

 植原体（Candidatus Phytoplasma）是一种没有细胞壁的原核微生物,主要由取食韧皮部的昆虫（叶蝉、飞虱等）传播, 也可由菟丝子寄生和嫁接等途径传播,常常引起植株黄化、丛枝、花器变态、萎缩等症状。迄今为止,世界上报道的植物植原体病害有1 000余种,仅我国就有100多种,造成巨大损失。     

Phytoplasmas infecting sour cherry and lilac represent two distinct lineages having close evolutionary affinities with clover phyllody phytoplasma

Phytoplasmas infecting sour cherry and lilac in Lithuania were found to represent two lineages related to clover phyllody phytoplasma (CPh), a subgroup 16SrI-(R/S)C (formerly 16SrI-C) strain exhibiting rRNA interoperon sequence heterogeneity. 16S rDNAs amplified from the cherry bunchy leaf (ChBL) and lilac little leaf (LcLL) phytoplasmas were identical or nearly identical to those of operon rrnA and operon rrnB, respectively, of CPh. There was no evidence of 16S rRNA interoperon sequence heterogeneity in either LcLL or ChBL phytoplasma. Based on collective RFLP patterns of 16S rDNA, ChBL was classified in subgroup 16SrI-R, and LcLL was classified in new subgroup 16SrI-S. The ribosomal protein (rp) gene sequences from LcLL phytoplasma were identical to those of CPh, and strain LcLL was classified in rp subgroup rpI-C. By contrast, rp gene sequences from ChBL phytoplasma differed from those of subgroup rpI-C; based on RFLP patterns of rp gene sequences, ChBL was classified in new rp subgroup rpI-O. Single nucleotide polymorphisms (SNPs), designated here by a new SNP convention, marked members of rp subgroup rpI-C, and distinguished LcLL and CPh from ChBL and other non-rpI-C phytoplasmas in group 16SrI. The results raise questions concerning phytoplasma biodiversity assessment based on rRNA genes alone and encourage the supplemental use of a single copy gene in phytoplasma identification and classification, while drawing attention to a possible role of horizontal gene transfer in the evolutionary history of these lineages.     

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     

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.     

Detection and identification of the maize bushy stunt phytoplasma in corn plants in Brazil using PCR and RFLP

Plants of corn (Zea mays L.) exhibiting symptoms of stunting and leaf reddening were assayed for the presence of phytoplasma gene sequences through the use of phytoplasma rRNA and ribosomal protein gene and maize bushy stunt (MBS) phytoplasma-specific oligonucleotide primers in polymerase chain reactions (PCR). Polymorphisms in 16S rDNA amplified from diseased plants were those characteristic of phytoplasmas classified in the16S rRNA gene group 16SrI, subgroup IB, of which MBS phytoplasma is a member. Amplification of ribosomal protein (rp) gene sequences in PCR primed by phytoplasma-specific primers confirmed presence of a phytoplasma in the diseased plants. Restriction fragment length polymorphism (RFLP) patterns of the amplified phytoplasma rp gene sequences were similar or identical to those observed for a known strain of MBS phytoplasma. In separate PCR, an MBS-specific oligonucleotide pair primed amplification of a MBS-characteristic DNA from templates derived from the diseased corn. Our data provide the first firm evidence for the presence of maize bushy stunt phytoplasma in corn in Brazil.     

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.