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1.
臭矢菜丛枝病植原体的分子鉴定研究 总被引:1,自引:0,他引:1
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。 相似文献
2.
海南省木豆丛枝病植原体的分子检测及鉴定 总被引:1,自引:0,他引:1
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。 相似文献
3.
利用植原体16S rDNA基因通用引物对新疆轮台县疑似杏褪绿卷叶病植株总DNA进行巢氏PCR检测,扩增出大小约1.2 kb的特异性条带。对扩增产物克隆和测序,确定特异片段大小为1248 bp。序列同源性比较和系统进化分析表明,新疆杏褪绿卷叶植原体不同分离株16S rDNA基因序列同源性极高,达到99.8%~100%。与16SrⅤ组成员的同源性达到98.2%以上,其中与16SrⅤ-B亚组的枣疯病植原体山东宝山分离株,甜樱桃绿化植原体山东分离株同源性最高,达到99.4%~99.6%。进一步虚拟RFLP分析,结果表明该植原体属于榆树黄化组(16SrⅤ)的一个新的亚组,与其相似性最高的是16SrⅤ-B亚组,相似系数为0.94。本研究首次报道了新疆杏褪绿卷叶植原体16S rDNA的序列,确定了其分类地位,为杏褪绿卷叶病的早期诊断和检测提供了基础。 相似文献
4.
利用分子生物学技术对天津滨海新区泡桐丛枝病病原进行分类鉴定。采用植原体16S rDNA通用引物R16mF2/R16mR1对患病植株总DNA进行PCR扩增,得到约1.4 kb特异性片段。克隆测序、Blast比对和iPhyClassifier分析结果表明,天津滨海新区泡桐丛枝植原体16S rDNA基因片段长1 432 bp,与国内泡桐丛枝植原体PY株系相似性最高,达99.86%,归属于16SrI组(aster yellows group,翠菊黄化组)D亚组。系统树构建与分析显示,泡桐丛枝病天津滨海株PaWB-TJBH与16SrI其他亚组亲缘关系较近,同在16SrI组进化枝上,与16Sr I-D组亲缘关系最近;16S rDNA序列RFLP电子酶切图谱表明,PaWB-TJBH属于16SrI-D组一个成员,与同源性比较和系统进化分析结果一致。 相似文献
5.
对仙人掌丛生幼嫩组织进行超薄切片电镜观察,在韧皮部筛管中存在大量植原体;根据植原体16S rRNA基因保守序列设计的通用引物对R16 F2/R2,应用PCR技术对仙人掌丛枝病进行分子检测,结果扩增到约1.2 kb的特异性片段,而在健康组织中却没有此特异片段;通过16S rDNA片段核酸序列同源性比较,结果表明仙人掌丛枝病植原体与花生丛枝病植原体亲缘关系最近,据此可初步判断仙人掌丛枝病植原体是一种属于16Sr Ⅱ组的植原体,基本确定了其分类地位。 相似文献
6.
本研究对河北省大面积发生的金莲花绿变病的病原进行检测和鉴定。以金莲花叶片的总DNA为模板,使用植原体16S rDNA和核糖体蛋白(ribosomal protein)基因rp的特异性引物进行PCR扩增,在感病金莲花样品中扩增到植原体的16S rDNA(1 432 bp)片段和rp基因(1 240 bp)片段。序列分析发现,获得的16S rDNA和rp基因片段与洋葱黄化植原体Onion yellows phytoplasma(GenBank登录号:AP006628)的相似度最高,分别为99.9%和99.3%,确定金莲花绿变病的病原为植原体,暂命名为金莲花绿变植原体Trollius chinensis virescence phytoplasma。对金莲花绿变植原体的16S rDNA进行虚拟RFLP分析,发现其酶切图谱与16SrⅠ-B亚组的洋葱黄化植原体的参照图谱完全一致,相似系数1.00。16S rDNA和rp基因的系统发育进化树显示,金莲花绿变植原体与16SrⅠ-B亚组的植原体聚为一支,属于植原体16S rⅠ-B亚组。 相似文献
7.
紫花苜蓿丛枝病植原体的分子检测及鉴定 总被引:1,自引:0,他引:1
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。 相似文献
8.
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? 相似文献
9.
利用植原体16SrRNA基因序列设计合成的引物,对表现丛枝的竹子植株总DNA进行直接PCR及巢式PCR扩增,得到长1.2kb的目的片段。将此片段与pGEMTEasy载体连接并转化到大肠杆菌DH5α感受态细胞中。通过酶切、PCR鉴定,对筛选得到的重组阳性克隆进行核酸序列测定及同源性比较分析,结果表明其与植原体16SrⅠ组中的西方翠菊黄化植原体(SAY)同源率为99%。依据16SrDNA序列建立了竹子丛枝病植原体株系的系统进化树。对云南竹子丛枝病植原体株系分类鉴定与已报道的结果相似。 相似文献
10.
小麦蓝矮植原体寄主范围的鉴定及RFLP分析 总被引:6,自引:0,他引:6
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。 相似文献
11.
ABSTRACT This paper describes the identification and differentiation of phytoplasmas by a highly sensitive diagnostic technique, DNA heteroduplex mobility assay (HMA). Closely related phytoplasma isolates of clover proliferation (CP), potato witches'-broom (PWB), and alfalfa witches'-broom (AWB) were collected from the field from 1990 to 1999. The entire 16S rRNA gene and 16/23S spacer region were amplified by polymerase chain reaction (PCR) from the field samples and standard CP, PWB, and AWB phytoplasmas and were subjected to restriction fragment length polymorphism (RFLP) analysis and HMA. Two subgroups (I and II) of phytoplasmas in the CP group were identified by HMA but not by RFLP analysis. The results were confirmed by 16/23S spacer region sequence data analysis. After HMA analyses of the PCR-amplified 16/23S spacer region, 14 phytoplasma isolates from field samples were classified into two aster yellows subgroups: subgroup I, phytoplasma isolates from China aster (Callistephus chinensis) yellows, French marigold (Tagetes patula) yellows, cosmos (Cosmos bipinnatus cv. Dazzler) yellows, clarkia (Clarkia unguiculata) yellows, California poppy (Eschscholzia californica cv. Tai Silk) yellows, monarda (Monarda fistulosa) yellows, and strawflower (Helichrysum bracteatum) yellows; and subgroup II, phytoplasma isolates from zinnia (Zinnia elegans cv. Dahlia Flower) yellows, Queen-Annes-Lace (Daucus carota) yellows, scabiosa (Scabiosa atropurpurea cv. Giant Imperial) yellows, Swan River daisy (Brachycombe multifida cv. Misty Pink) yellows, pot marigold (Calendula officinalis) yellows, purple coneflower (Echinacea purpurea) yellows, and feverfew (Chrysanthemum parthenium) yellows. The results indicate that HMA is a simple, rapid, highly sensitive and accurate method not only for identifying and classifying phytoplasmas but also for studying the molecular epidemiology of phytoplasmas. 相似文献
12.
Distinctions between phytoplasmas at the subgroup level detected by heteroduplex mobility assay 总被引:2,自引:1,他引:2
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. 相似文献
13.
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. 相似文献
14.
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. 相似文献
15.
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。 相似文献
16.
广东枣疯病植原体的鉴定 总被引:1,自引:1,他引:0
Several jujube plants with witches′ broom, little leaf, and big bud symptoms, which were likely infected by jujube witches′ broom (JWB) phytoplasma, were collected in Guangzhou, Guangdong Province. To identify the pathogen, PCR was performed using phytoplasma 16S rDNA universal primer pairs R16mF2/R1 and P1/P7 and SecA gene primer pair SecAfor1/rev3 with total DNA of the symptomatic plants as templates. Specific fragments, 1.4 kb, 1.8 kb, and 0.8 kb in length, were amplified from one of three symptomatic samples. Phylogenetic analysis based on 16S rDNA verified that the pathogen harming jujube plants in Guangzhou was jujube witches′ broom phytoplasma which belonged to 16SrV-B subgroup. Comparison results also showed that the 16S rDNA sequence of Guangzhou JWB phytoplasma shared the highest nucleotide identity (100%) with the reported jujube witches′ broom phytoplasma Japanese strain (AB442218) and JWB strain (AY197661) and shared the nucleotide identity ranging from 99.74% to 99.80% with the other JWB phytoplasma strains. In addition, phylogenetic analysis based on SecA also showed that Guangzhou jujube witches′ broom phytoplasma belonged to 16SrV-B subgroup and shared 99.28%-99.76% similarity with other phytoplasma strains. All these results suggested that jujube witches′ broom phytoplasma has infected jujube plants in Guangdong Province. 相似文献
17.
J. Wang X.‐P. Zhu R. Gao C.‐L. Lin Y. Li Q.‐C. Xu C.‐G. Piao X.‐D. Li H.‐F. Li G.‐Z. Tian 《Plant pathology》2010,59(5):972-981
This study determined the tuf gene sequence of the phytoplasma specific to paulownia witches’‐broom from Nanyang, China (hereby designated PaWB‐Ny). The PaWB‐Ny tuf gene was 1185 nucleotides in length and confirmed that the phytoplasma belongs to subgroup 16SrI‐D of aster yellows. Three characteristic GTP‐binding protein motifs were identified based on the peptide deduced from the tuf gene sequence. Results suggested that the elongation factor EF‐Tu was localized in the cytoplasm and lacked hydrophobic transmembrane domains. Antibodies against PaWB‐Ny EF‐Tu were prepared by rabbit immunization with glutathione‐S‐transferase (GST)‐tagged EF‐Tu fusion protein expressed in Escherichia coli. EF‐Tu exhibited a molecular weight of ~43 kDa and was detected in PaWB‐infected paulownia plants by western blot analysis. Indirect enzyme‐linked immunosorbent assays (ELISA) and dot blotting analyses were performed with freezing and thawing treatments during antigen preparation. Dilution of extracts to an appropriate scale significantly reduced non‐specific reactions. The resultant PaWB EF‐Tu antibody reacted with antigens from plants infected with periwinkle virescence and chinaberry tree witches’‐broom phytoplasmas, but not those infected with jujube witches’‐broom or bishopwood witches’‐broom phytoplasma. The EF‐Tu was characteristically localized within the phytoplasmal cytoplasm of infected plant phloem tissues. 相似文献
18.
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 相似文献
19.
Manabu KUSUNOKI Toshiki SHIOMI Motowo KOBAYASHI Torao OKUDAIRA Akihiro OHASHI Teruo NOHIRA 《Journal of General Plant Pathology》2002,68(2):147-154
Phytoplasmas causing a severe decline of three tree species, i.e., Rhus javanica, Hovenia tomentella and Zizyphus jujuba, in Japan were examined for their transmissibility by a leafhopper species Hishimonus sellatus, and for their phylogenetic relatedness. By H. sellatus, Rhus yellows (RhY) phytoplasma was transmissible to white clover and periwinkle seedlings, causing typical symptoms in these
plants. Jujube witches' broom (JWB) phytoplasma was also transferred to the host plant, Z. jujuba, by the leafhopper. Because JWB phytoplasma was transmitted to Hovenia tomentella and caused the same symptoms as Hovenia witches' broom (HWB), JWB phytoplasma may be very closely related to HWB phytoplasma.
RFLP analysis of the PCR products of 16S rDNA revealed that RhY phytoplasma belongs to the Aster yellows (AY) group, and JWB
and HWB phytoplasmas belong to a different group (possibly Elm yellows group). Thus, we found that one species of leafhopper
can carry phylogenetically distant phytoplasmas.
Received 23 April 2001/ Accepted in revised form 29 October 2001 相似文献