中国各地不同枣树品种上枣疯病植原体的PCR检测及分子变异分析

摘要：【目的】检测不同地区枣树品种上的枣疯植原体侵染及保守基因序列的变异。【方法】利用植原体16S rDNA的通用引物R16mF2／R16mR1、16S-23S间区序列(SR)的通用引物SR1/SR及secY基因引物FD9f/r,通过PCR检测采自国内7个地区14个枣树品种上的32个枣疯病和4个酸枣丛枝病样品。将PCR产物进行直接或克隆测序,结合已报导的测序数据,进行序列同源性和系统进化分析。【结果】所有枣疯病样品中均检测到植原体;皆属于榆树黄化16S rV-B亚组,与我国重阳木丛枝和樱桃致死黄化遗传关系     

Development of molecular markers and a diagnostic tool for investigation of coinfections by and interactions between potato purple top and potato witches'‐broom phytoplasmas in tomato

Columbia Basin potato purple top (PPT) phytoplasma and Alaska potato witches'‐broom (PWB) phytoplasma are two closely related but mutually distinct pathogenic bacteria that infect potato and other vegetable crops. Inhabiting phloem sieve elements and being transmitted by phloem‐feeding insect vectors, both pathogens are affiliated with ‘Candidatus Phytoplasma trifolii’ and are members of the clover proliferation phytoplasma group (16SrVI). The polyphagous nature and wide geographic distribution of their insect vectors make mixed infection inevitable. In this study, we experimentally constituted a simultaneous PPT and PWB phytoplasma infection in tomato (Solanum lycopersicum) and developed a sensitive diagnostic tool to investigate mixed infections by and in planta interactions of the two phytoplasmas. The distribution and relative abundance of the two co‐infecting phytoplasmas were monitored over a 45‐day post‐infection time course and for three serial passages in planta. Our results revealed that dual infections of the two phytoplasmas induce a new symptom unseen in infection by either phytoplasma alone. Our results also raised an interesting question as to whether the two phytoplasmas differ in ability of competitive dominance under co‐infection conditions. The molecular markers and the diagnostic tool devised in this study should be useful for further investigations of the interactions between the two closely related phytoplasmas in their hosts.     

Molecular biology and pathogenicity of phytoplasmas

Phytoplasmas are a large group of plant‐pathogenic wall‐less, non‐helical, bacteria associated with diseases, collectively referred to as yellows diseases, in more than a thousand plant species worldwide. Many of these diseases are of great economic importance. Phytoplasmas are difficult to study, in particular because all attempts at culturing these plant pathogens under axenic conditions have failed. With the introduction of molecular methods into phytoplasmology about two decades ago, the genetic diversity of phytoplasmas could be elucidated and a system for their taxonomic classification based on phylogenetic traits established. In addition, a wealth of information was generated on phytoplasma ecology and genomics, phytoplasma–plant host interactions and phytoplasma–insect vector relationships. Taxonomically, phytoplasmas are placed in the class Mollicutes, closely related to acholeplasmas, and are currently classified within the provisional genus ‘Candidatus Phytoplasma’ based primarily on 16S rDNA sequence analysis. Phytoplasmas are characterised by a small genome. The sizes vary considerably, ranging from 530 to 1350 kilobases (kb), with overlapping values between the various taxonomic groups and subgroups, resembling in this respect the culturable mollicutes. The smallest chromosome, about 530 kb, is known to occur in the Bermuda grass white leaf agent ‘Ca. Phytoplasma cynodontis’. This value represents the smallest mollicute chromosome reported to date. In diseased plants, phytoplasmas reside almost exclusively in the phloem sieve tube elements and are transmitted from plant to plant by phloem‐feeding homopteran insects, mainly leafhoppers and planthoppers, and less frequently psyllids. Most of the phytoplasma host plants are angiosperms in which a wide range of specific and non‐specific symptoms are induced. Phytoplasmas have a unique and complex life cycle that involves colonisation of different environments, the plant phloem and various organs of the insect vectors. Furthermore, many phytoplasmas have an extremely wide plant host range. The dynamic architecture of phytoplasma genomes, due to the occurrence of repetitive elements of various types, may account for variation in their genome size and adaptation of phytoplasmas to the diverse environments of their plant and insect hosts. The availability of five complete phytoplasma genome sequences has made it possible to identify a considerable number of genes that are likely to play major roles in phytoplasma–host interactions. Among these, there are genes encoding surface membrane proteins and effector proteins. Also, it has been shown that phytoplasmas dramatically alter their gene expression upon switching between plant and insect hosts.     

Detection and Identification of an Elm Yellows Group Phytoplasma Associated with Camellia in China

In 2012, yellowing of camellias was observed in Tai'an in Shandong province, China. Transmission electron microscopy (TEM) revealed phytoplasma in the phloem sieve tube elements of symptomatic plants. A specific fragment of phytoplasma 16S rRNA gene was amplified by polymerase chain reaction (PCR) using the universal phytoplasma primers P1/P7 followed by R16F2n/R16R2. Sequence and restriction fragment length polymorphism (RFLP) analyses allowed us to classify the detected phytoplasma into the elm yellows (EY) group (16SrV), subgroup 16SrV‐B. Sequence analyses of the ribosomal protein (rp) gene confirmed a close relationship with phytoplasmas belonging to the rpV‐C subgroup. Thus, the phytoplasma associated with yellows disease in camellia, designated as ‘CY’, is a member of the 16SrV‐B subgroup. This is the first report of phytoplasma associated with camellia.     

Detection, Identification and Molecular Characterization of a Phytoplasma Associated with Arabian Jasmine (Jasminum sambac L.) Witches' Broom in Oman

Arabian jasmine (Jasminum sambac L.) plants showing witches’ broom (WB) symptoms were found in two regions in the Sultanate of Oman. Polymerase chain reaction (PCR) amplification of the 16S rRNA gene and the 16S–23S spacer region utilizing phytoplasma‐specific universal and designed primer pairs, and transmission electron microscopy of phytoplasma‐like structures in phloem elements confirmed phytoplasma infection in the symptomatic plants. PCR products primed with the P1/P7 primer pair were 1804 bp for jasmine witches’ broom (JasWB) and 1805 bp for alfalfa (Medicago sativa L.) witches’ broom (AlfWB). Actual and putative restriction fragment length polymorphic analysis indicated that jasmine and AlfWB phytoplasmas were molecularly indistinguishable from each other and closely related to papaya yellow crinkle (PYC), as well as being distinct from lime WB (LWB) and Omani alfalfa WB (OmAlfWB) phytoplasmas. A sequence homology search of JasWB and AlfWB showed 99.8% similarity with PYC from New Zealand and 99.6% similarity with each other (JasWB/AlfWB). The jasmine and AlfWB phytoplasmas were also shown to be related to the peanut WB group (16SrII) of 16S rRNA groups based on a phylogenetic tree generated from phytoplasma strains primed with the P1/P7 primer pair and representing the 15 phytoplasma groups.     

Identification of aster yellows phytoplasma in garlic and green onion by PCR-based methods

In the summer of 1999, typical yellows-type symptoms were observed on garlic and green onion plants in a number of gardens and plots around Edmonton, Alberta, Canada. DNA was extracted from leaf tissues of evidently healthy and infected plants. DNA amplifications were conducted on these samples, using two primer pairs, R16F2n/R2 and R16(1)F1/R1, derived from phytoplasma rDNA sequences. DNA samples of aster yellows (AY), lime witches'-broom (LWB) and potato witches'-broom (PWB) phytoplasmas served as controls and were used to determine group relatedness. In a direct polymerase chain reaction (PCR) assay, DNA amplification with universal primer pair R16F2n/R2 gave the expected amplified products of 1.2 kb. Dilution (1/40) of each of the latter products were used as template and nested with specific primer pair R16(1)F1/R1. An expected PCR product of 1.1 kb was obtained from each phytoplasma-infected garlic and green onion samples, LWB and AY phytoplasmas but not from PWB phytoplasma. An aliquot from each amplification product (1.2 kb) with universal primers was subjected to PCR-based restriction fragment length polymorphism (RFLP) to identify phytoplasma isolates, using four restriction endonucleases (AluI, KpnI, MseI and RsaI). DNA amplification with specific primer pair R16(1)F1/R1 and RFLP analysis indicated the presence of AY phytoplasma in the infected garlic and green onion samples. These results suggest that AY phytoplasma in garlic and green onion samples belong to the subgroup 16Sr1-A.     

Detection of aster yellows phytoplasma in false flax based on PCR and RFLP

False flax (Camelina sativa L.) plants were found to be infected with a yellows-type disease caused by a phytoplasma in experimental plots at the Edmonton Research station. Alberta, Canada. Typical phytoplasmas were detected in the phloem cells in ultrathin sections from leaf midrib tissues examined by electron microscopy. These observations were supported by polymerase chain reaction (PCR) using two primer pairs, R16 F2n/R2 and R16(1)F1/R1, derived from phytoplasma rDNA sequences. Aster yellows (AY) and potato witches'-broom (PWB) phytoplasma DNA samples served as controls and were used to study group relatedness. In a direct PCR assay, DNA amplification with universal primer pair R16F2n/R2 gave the expected PCR products of 1.2 kb. Based on a nested-PCR assay using the latter PCR products as templates, and a specific primer pair, R16(1)F1/R1, designed on the basis of AY phytoplasma rDNA sequences, a PCR product of 1.1 kb was obtained from each phytoplasma-infected false flax and AY sample, but not from PWB phytoplasma and healthy controls. DNA amplification with specific primer pair R16(1)F1/R1 and restriction fragment length polymorphism indicated the presence of AY phytoplasma in the infected false flax sample. This is the first reported characterization of AY phytoplasma in false flax.     

First Report of a 16SrI‐C Phytoplasma Infecting Celery (Apium graveolens) with Stunting,Bushy Top and Phyllody in the Czech Republic

Apium graveolens L. plants showing stunting, purplish/whitening of new leaves, flower abnormalities and bushy tops were observed in South Bohemia (Czech Republic) during 2011 and 2012. Transmission electron microscopy observations showed phytoplasmas in phloem sieve tube elements of symptomatic but not healthy plants. Polymerase chain reactions with universal and group‐specific phytoplasma primers followed by restriction fragment length polymorphism analyses and sequencing of 16S rDNA enabled classification of the detected phytoplasmas into the aster yellows group, ribosomal subgroup 16SrI‐C. Identical analyses of the ribosomal protein genes rpl22 and rps3 were used for further classification and revealed affiliation of the phytoplasmas with the rpIC subgroups. This is the first report of naturally occurring clover phyllody phytoplasma in A. graveolens in both the Czech Republic and worldwide.     

Structural Evidence for Plastid Inclusions as a Possible 'Sealing' Mechanism in the Phloem of Monocotyledons

Sieve elements in monocotyledons possess unique plastids. Structuralevidence indicates that when mature sieve-tube members are mechanicallyperturbed the plastids release proteinaceous, quasi –crystalline inclusions. The inclusions become lodged in sieve-platepores and appear to seal portions of phloem sieve tubes.     

Comparative Anatomy of Secondary Phloem in Celastraceae

A comparative anatomical study on the secondary phloem of 5-genera, 10 species in Celastraceae was carried out. Based on the phloem structure characters, 3 phloem types were observed. In type Ⅰ , as seen in 5 species of Euonymus, the sieve-tube elements have more inclined end walls and numerous sieve areas (compound sieve plates), phloem rays are almost uniseriate. Type Ⅱ is seen in Celastrus and Tripterygium. It has relatively short sievetube elements, slight inclined end wall and sparse number of sieve areas: the phloem fiber is not lignified and ray is multiseriate. Type Ⅲ is observed in Dipentodon and Perrottetia, the sieve-tube elements are with simple sieve plate, the end wall is almost transverse, there are sclereid and fiber groups in the nonfounctional phloem, and phloem rays are uniseriate or biseriate.     

Heteroduplex mobility assay detects DNA mutations for differentiation of closely related phytoplasma strains

We present the first use of DNA heteroduplex mobility assay (HMA) to detect the point mutations including substitutions and deletions/insertions in 16S rDNA of aster yellows phytoplasma (AY27) and to differentiate phytoplasmas collected from field samples of clover proliferation (CP) and alfalfa witches'-broom (AWB). The phytoplasmal 16S rDNA fragment was amplified from AY27 by polymerase chain reaction (PCR) and cloned into a plasmid vector. The cloned DNA fragment was subjected to in vitro mutation to produce 1- to 4-base substitutions and 1- to 3-base deletions. The mutated 16S rDNA fragments were analyzed by HMA. The results showed that a single two-base substitution or a single-base deletion/insertion in the 529 bp DNA fragment was directly detected and that a DNA divergence at a level of as low as 0.2% was detectable by HMA. Heteroduplex mobilities were affected by the number and composition of the phytoplasma DNA bases in mismatches or gaps and were proportional to the degree of DNA divergences. Gaps caused greater retardation in heteroduplex mobility than mismatches did. HMA was highly sensitive in detecting the mixed infections of phytoplasmas. In analyses of CP and AWB field samples collected in Alberta, two CP and one AWB phytoplasma isolates were differentiated from others by HMA but not by restriction fragment length polymorphism (RFLP). Therefore, HMA provides a simple, rapid, highly sensitive and analytical method to detect and estimate the genetic divergence of phytoplasmas when other methods such as RFLP are not readily applicable.     

Comparative Molecular Analyses of Phytoplasmas infecting Sophora japonica cv. golden and Robinia pseudoacacia

Phytoplasmas were detected in Sophora japonica cv. golden and Robinia pseudoacacia with diseased branches of witches'‐broom collected in Haidian district, Beijing, China. Phytoplasma cells were observed in phloem sieve elements of symptomatic S. japonica cv. golden by transmission electron microscopy. The presence of phytoplasmas was further confirmed by sequence determination of partial gene sequences of 16S rDNA, rp (ribosomal protein) and secY. Phylogenetic trees and virtual restriction fragment length polymorphism (RFLP) analyses indicated that the phytoplasmas causing S. japonica cv. golden witches'‐broom (SJGWB) and R. pseudoacacia witches'‐broom (RPWB) belong to the 16SrV (elm yellows) group, and they are most closely related to subgroup 16SrV‐B, rpV‐C and secYV‐C jujube witches'‐broom (JWB) phytoplasma. Comparative analyses indicated that the phytoplasma of RPWB was closer to the JWB and that R. pseudoacacia might serve as an alternative host plant of JWB phytoplasma.     

A picornavirus-like pathogen of Cotylogaster occidentalis (Trematoda: Aspidogastrea), an intestinal parasite of freshwater mollusks

Nonoccluded, icosahedral picornavirus-like (PVL) particles, 23 nm in diameter, forming paracrystalline arrays were seen in the cytoplasm of various cells in Cotylogaster occidentalis. Viral inclusions were visible in live specimens and in sections prepared for light and electron microscopy. All worms examined over a 2-year period were found to be infected. Infections were naturally acquired and susceptibility was not associated with any particular developmental stages. Development of viral inclusions involved an increase in the inclusion volume, progressive accumulation and condensation of materials into the interior of the inclusions, and formation of multilamellar membrane networks. Virus particles were observed in the stroma of the inclusions in association with multilamellar spherical bodies. Mature PVL particles aggregated into polygonally shaped paracrystalline arrays. When such arrays occurred in the surface tegument, local disruption of the tegumentary membrane may liberate these particles into the environment. PVL particle production did not exhaust glycogen content of infected cells and did not appear to affect short-term survival of the parasite outside the molluscan host.     

ONTOGENY AND STRUCTURE OF THE SECONDARY PHLOEM IN PYRUS MALUS

Evert , Ray F. (U. Wisconsin, Madison.) Ontogeny and structure of the secondary phloem in Pyrus malus. Amer. Jour. Bot. 50(1): 8–37. Illus. 1963.—The secondary phloem of apple consists of sieve-tube elements, companion cells, phloem parenchyma cells, fiber-sclereids, and ray parenchyma cells. The sieve-tube elements are generally long, slender cells with very oblique end walls and much-compounded sieve plates. All sieve-tube elements initially possess nacreous thickenings. Similar wall thickenings were observed in the differentiating fiber-sclereids and xylem elements. Of the 245 sieve-tube elements critically examined, 242 were associated with companion cells. All of the companion cells were shorter than their associated sieve-tube elements. Young companion cells possess slime bodies which later become dispersed. Callose is often found on the sieve-tube element side of the common wall between sieve-tube element and companion cell. In several collections, callose was found on both sides of that wall. The parenchyma cells are of 3 types: crystal-containing cells; tannin-and/or starch-containing cells; and those with little or no tannins or starch. Any type parenchyma cell may be on to genetically related to a sieve-tube element, that is, may be derived from the same phloem initial as the sieve-tube element. Morphologically, the phloem parenchyma cells intergrade with the companion cells, the tannin- and starch-free parenchyma cells often being difficult to distinguish from companion cells. Most of the tannin- and starch-free parenchyma cells collapse when the contiguous sieve-tube elements become nonfunctional. The fiber-sclereids arise from parenchyma cells which overwinter on the margin of the cambial zone and differentiate in nonfunctional phloem.     

Association of a phytoplasma with a yellow leaf syndrome of sugarcane in Africa

Evidence is presented for the association of a phytoplasma, provisionally named sugarcane yellows phytoplasma (ScYP), in sugarcane affected by a yellow leaf syndrome. The phytoplasma was consistently detected in leaves of more than 40 varieties from eight African countries. It was present in all symptomatic as well as some asymptomatic field grown cane samples but not in plants grown from true seed, and it was also observed in phloem sieve tubes by transmission electron microscopy. Phytoplasma 16S rDNA was confirmed by PCR, and restriction fragment analysis using Rsal and Haelll confirmed that PCR-amplified products were of phytoplasma rather than of plant or of other pathogen origin. Sequences obtained from the intergenic spacer region, between the 16S and 23S rDNA genes, confirmed the identity of the phytoplasma as belonging to the western X group of phytoplasmas.     

Distribution of phytoplasmas in infected plants as revealed by real-time PCR and bioimaging

Phytoplasmas are cell wall-less bacteria inhabiting the phloem and utilizing it for their spread. Infected plants often show changes in growth pattern and a reduced crop yield. A quantitative real-time polymerase chain reaction (Q-PCR) assay and a bioimaging method were developed to quantify and localize phytoplasmas in situ. According to the Q-PCR assay, phytoplasmas accumulated disproportionately in source leaves of Euphorbia pulcherrima and, to a lesser extent, in petioles of source leaves and in stems. However, phytoplasma accumulation was small or nondetectable in sink organs (roots and sink leaves). For bioimaging, infected plant tissue was stained with vital fluorescence dyes and examined using confocal laser scanning microscopy. With a DNA-sensitive dye, the pathogens were detected exclusively in the phloem, where they formed dense masses in sieve tubes of Catharanthus roseus. Sieve tubes were identified by counterstaining with aniline blue for callose and multiphoton excitation. With a potentiometric dye, not all DNA-positive material was stained, suggesting that the dye stained metabolically active phytoplasmas only. Some highly infected sieve tubes contained phytoplasmas that were either inactive or dead upon staining.     

LEAF OF SPINACIA OLERACEA (SPINACH): ULTRASTRUCTURE,AND PLASMODESMATAL DISTRIBUTION AND FREQUENCY,IN RELATION TO SIEVE-TUBE LOADING

Minor veins and contiguous tissues of the Spinacia oleracea leaf were analyzed by electron microscopy to determine the characteristics of the component cells and the structure, distribution, and frequency of plasmodesmata between the various cell types of the leaf. Mesophyll and bundle-sheath cells contain components typical of photosynthetic cells although the latter cell type contains smaller chloroplasts and fewer mitochondria and microbodies than the mesophyll cells. In addition, the mesophyll cells contain numerous invaginations of the plasmalemma bordering the chloroplasts and evaginations of the outer membrane of the opposing chloroplast envelope. In places, these membranes appear continuous with each other. The minor veins consist of tracheary elements, xylem parenchyma cells, sieve-tube members, companion and phloem parenchyma cells, and other cells simply designated vascular parenchyma cells. The companion and phloem parenchyma cells are typically larger than the sieve-tube members with the companion cells containing a much denser cytoplasm that the phloem parenchyma. Cytoplasmic connections occur along all possible routes from the mesophyll to the sieve-tube members and consist of either simple or branched plasmodesmata between parenchymatic elements or pore-plasmodesmata between the sieve-tube members and parenchyma cells. The highest frequency of plasmodesmata occurs between the sieve-tube members and companion cells, although the value is essentially the same as between the various parenchymatic elements of the phloem. Compared to several previously studied species, the frequency of plasmodesmata between cell types of the spinach leaf is low. These results are discussed in relation to apoplastic vs. symplastic solute transport and sieve-tube loading in this species.     

Laser microdissection of grapevine leaf phloem infected by stolbur reveals site‐specific gene responses associated to sucrose transport and metabolism

Bois Noir is an emergent disease of grapevine that has been associated to a phytoplasma belonging to the XII‐A stolbur group. In plants, phytoplasmas have been found mainly in phloem sieve elements, from where they spread moving through the pores of plates, accumulating especially in source leaves. To examine the expression of grapevine genes involved in sucrose transport and metabolism, phloem tissue, including sieve element/companion cell complexes and some parenchyma cells, was isolated from healthy and infected leaves by means of laser microdissection pressure catapulting (LMPC). Site‐specific expression analysis dramatically increased sensitivity, allowing us to identify specific process components almost completely masked in whole‐leaf analysis. Our findings showed decreased phloem loading through inhibition of sucrose transport and increased sucrose cleavage activity, which are metabolic changes strongly suggesting the establishment of a phytoplasma‐induced switch from carbohydrate source to sink. The analysis focused at the infection site also showed a differential regulation and specificity of two pathogenesis‐related thaumatin‐like genes (TL4 and TL5) of the PR‐5 family.     

Detection and Identification of Phytoplasmas in Pomegranate Trees with Yellows Symptoms

Symptoms resembling those associated with phytoplasma presence were observed in pomegranate (Punica granatum L.) trees in June 2012 in the Aegean Region of Turkey (Ayd?n province). The trees exhibiting yellowing, reduced vigour, deformations and reddening of the leaves and die‐back symptoms were analysed to verify phytoplasma presence. Total nucleic acids were extracted from fresh leaf midribs and phloem tissue from young branches of ten symptomatic and five asymptomatic plants. Nested polymerase chain reaction assays using universal phytoplasma‐specific 16S rRNA and tuf gene primers were performed. Amplicons were digested with Tru1I, Tsp509I and HhaI restriction enzymes, according to the primer pair employed. The phytoplasma profiles were identical to each other and to aster yellows (16SrI‐B) strain when digestion was carried out on 16Sr(I)F1/R1 amplicons. However, one of the samples showed mixed profiles indicating that 16SrI‐B and 16SrXII‐A phytoplasmas were present when M1/M2 amplicons were digested, the reamplification of this sample with tuf cocktail primers allowed to verify the presence of a 16SrXII‐A profile. One pomegranate aster yellows strain AY‐PG from 16S rRNA gene and the 16SrXII‐A amplicon from tuf gene designed strain STOL‐PG were directly sequenced and deposited in GenBank under the Accession Numbers KJ818293 and KP161063, respectively. To our knowledge, this is the first report of 16SrI‐B and 16SrXII‐A phytoplasmas in pomegranate trees.