Apple proliferation resistance of <Emphasis Type="Italic">Malus sieboldii</Emphasis>-based rootstocks in comparison to rootstocks derived from other <Emphasis Type="Italic">Malus</Emphasis> species

In three trials carried out over a period of 24 years, open-pollinated seedlings of Malus sieboldii and M. sargentii and 22 apomictic rootstock selections with either M. sieboldii, M. sargentii or M. hupehensis in their parentage were examined for apple proliferation (AP) resistance in comparison to clonal M. x domestica-based rootstocks M 9, M 11, M 13, stocks of the B (Budagovski) and the Polish P series and M. robusta seedlings. Following experimental inoculation or natural infection the Golden Delicious-grafted trees on most of the M. sieboldii-derived progenies showed a high level of AP resistance expressed by low cumulative disease indices, a high percentage of non or little affected trees, low incidence of the small fruit symptom and non or little effect on vigour. Trees on M 9 and M 11, B 118 and M. robusta seedlings were moderately susceptible while trees on progenies with M. sargentii and M. hupehensis parentage, rootstocks of the P series, B 9, B 490 and M 13 proved highly susceptible. The screening also showed that rootstocks with M. sieboldii and M. sargentii parentage are often highly susceptible to latent apple viruses. Trees on most of the M. sieboldii-based progenies were more vigorous than trees on standard stock M 9, whereas the vigour of some progenies from selections with M. sargentii parentage was in the range of M 9 or even lower. Productivity was often correlated with the vigour.     

山定子抗苹果褐斑病菌侵染过程中DNA ladder与类caspases活性的检测

接种褐斑病菌分生孢子悬浮液于山定子与富士苹果叶片,接种后1、3 d和5 d取样,提取DNA,检测DNA ladder;提取样品粗蛋白,用特异性荧光底物检测粗蛋白中类caspase活性,探索山定子受褐斑病菌侵染过程中引起的细胞程序性死亡(PCD)与抗性的关系,检测DNA ladder和类caspases活性变化的规律。研究发现:在接种后1、3 d和5 d,山定子和富士苹果叶片中没有明显DNA ladder的产生;受检测的YVADase、DEVDase、IETDase和VEIDase活性在接种后1 d和3 d没有显著变化,但在接种后5 d,活性均降低30%左右,显著低于对照。研究表明,山定子在褐斑病菌侵染过程中并没有DNA ladder产生,但却伴随着类caspase活性的下降。     

A rapid virulence assay for the Dutch elm disease fungus Ophiostoma novo‐ulmi by inoculation of apple (Malus × domestica ‘Golden Delicious’) fruits

Large‐scale virulence tests using trees or saplings are expensive, time‐consuming and require a considerable amount of space. The suitability of using ‘Golden Delicious’ apples as a rapid screen for identifying Ophiostoma novo‐ulmi transformants with reduced virulence was thus evaluated. When a collection of O. novo‐ulmi field isolates belonging to subspecies novo‐ulmi or americana was inoculated to apples, members of subsp. novo‐ulmi induced, on average, larger necrotic lesions than subsp. americana isolates. The size of the lesions on apples was not correlated with mycelial growth rate of isolates on nutrient agar. Insertional mutants from O. novo‐ulmi subsp. novo‐ulmi isolate H327 were inoculated to ‘Golden Delicious’ apples and Ulmus parvifolia × U. americana saplings in parallel experiments. Results clearly indicated that the O. novo‐ulmi transformants included several exhibiting significantly altered levels of virulence. Variability among replicates within a treatment was reduced in apple inoculation data compared to elm sapling data. Overall, the ‘Golden Delicious’ apple assay was found to be an excellent means for rapidly assessing the virulence level of O. novo‐ulmi isolates.     

Evaluation of a pheromone trap for the cotton pink bollworm Pectinophora gossypiella Saunders

This 4-year study examined the susceptibility of nine cultivars of apple, Malus domestica Borkhausen to attack by woolly apple aphid (WAA), Eriosoma lanigerum in Jordan. The cultivars under investigation were: Prima Rouge, Delberd Steval, Early Gold, Starking Delicious, Harmony, Golden Smoothee, Fuji, Melrose, and Golden Delicious. Estimation of susceptibility was based upon a numeric scale of 0–4 for both root and shoot, but each with different specifications. A tree infestation rating was obtained by calculating the average rating of both edaphic and arboreal ratings of each tree. Fuji was significantly the most infested cultivar during the period of study and it ranked as a highly susceptible cultivar. Prima Rouge, Early Gold, Starking Delicious, Golden Smoothee, and Golden Delicious showed lower susceptibility. Harmony was an immune cultivar as it sustained neither edaphic (root inhabiting) nor arboreal colonies of woolly apple aphid. We propose the development of rootstocks from Harmony cultivar. The latter offers a new gene for resistance to WAA that will open the door for plant breeders to produce different resistant rootstocks.     

Genetic and serological analyses of elongation factor EF‐Tu of paulownia witches’‐broom phytoplasma (16SrI‐D)

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.     

Experimental and molecular evidence of Reptalus panzeri as a natural vector of bois noir

Bois noir (BN) is an economically important grapevine yellows disease induced by the stolbur phytoplasma and principally vectored by the cixiid Hyalesthes obsoletus. This study addresses the involvement of other planthoppers and/or leafhoppers in BN epidemics in the South Banat district of northeastern Serbia, by performing transmission experiments and multilocus typing of stolbur phytoplasma isolates to determine the vector‐related characteristics of the disease. Transmission trials were conducted with adults of two cixiid congeners, Reptalus panzeri and R. quinquecostatus, which were found to harbour stolbur phytoplasma in the vineyards under study. A molecular characterization of stolbur phytoplasma isolates was performed by sequence analysis and/or RFLP typing of the two housekeeping genes tuf and secY and the two membrane proteins stamp and vmp1. Transmission trials with naturally infected R. panzeri adults from either the BN‐infected vineyards or maize redness (MR)‐affected maize fields revealed a high stolbur phytoplasma transmission efficiency to grapevines. In contrast, experiments conducted with stolbur‐positive R. quinquecostatus originating from BN‐infected vineyards, provided no evidence for a vector role of this species. Seven stolbur phytoplasma genotypes, all of which were tuf‐b types, were detected among the grapevine‐ and insect‐associated field samples according to the tuf/secY/vmp1/stamp typing. STOLg was the genotype most frequently found in naturally infected grapevine (42%), as well as R. panzeri originating from the vineyards (85%) and maize fields (98%). The same genotype was found in all experimental plants inoculated by R. panzeri, confirming its vectorship of the disease.     

Range of phytoplasma concentrations in various plant hosts as determined by competitive polymerase chain reaction

ABSTRACT For competitive polymerase chain reaction (PCR), an internal standard DNA template was developed that consisted of a highly conserved, internally deleted 16S rDNA fragment of an aster yellows phytoplasma. The internal standard was calibrated using a quantified culture of Acholeplasma laidlawii. Serial dilutions of the internal standard and fixed amounts of target templates from infected plants were coamplified with the same primers, and the products obtained were quantified using an enzyme-linked immunosorbent assay procedure. Analysis of the data revealed that the phytoplasma concentration in the plants examined differed by a factor of about 4 x 10(6). Phytoplasma concentrations of 2.2 x 10(8) to 1.5 x 10(9) cells per g of tissue were identified in periwinkles infected with various phytoplasmas. High to moderate concentrations were detected in Malus domestica (apple) genotypes infected with the apple proliferation phytoplasma, Alnus glutinosa (alder) genotypes infected with the alder yellows phytoplasma, and most aster yellows-infected Populus (poplar) genotypes examined. Very low phytoplasma concentrations, ranging from 370 to 34,000 cells per g of tissue, were identified in proliferation-diseased apple trees on resistant rootstocks 4551 and 4608, yellows-diseased Quercus robur (oak) trees, and Carpinus betulus (hornbeam) trees. Such low concentrations, which corresponded to about 4 to 340 cells in the reaction mixture, could only be detected and quantified by nested PCR.     

The insect vector Cacopsylla picta vertically transmits the bacterium ‘Candidatus Phytoplasma mali’ to its progeny

The phloem‐sucking psyllid Cacopsylla picta plays an important role in transmitting the bacterium ‘Candidatus Phytoplasma mali’, the agent associated with apple proliferation disease. The psyllid can ingest ‘Ca. Phytoplasma mali’ from infected apple trees and spread the bacterium by subsequently feeding on uninfected trees. Until now, this has been the most important method of ‘Ca. Phytoplasma mali’ transmission. The aim of this study was to investigate whether infected C. picta are able to transmit ‘Ca. Phytoplasma mali’ directly to their progeny. This method of transmission would allow the bacteria to bypass a time‐consuming reproductive cycle in the host plant. Furthermore, this would cause a high number of infected F₁ individuals in the vector population. To address this question, eggs, nymphs and adults derived from infected overwintering adults of C. picta were reared on non‐infected apple saplings and subsequently tested for the presence of ‘Ca. Phytoplasma mali’. In this study it was shown for the first time that infected C. picta individuals transmit ‘Ca. Phytoplasma mali’ to their eggs, nymphs and F₁ adults, thus providing the basis for a more detailed understanding of ‘Ca. Phytoplasma mali’ transmission by C. picta.     

PM 7/62 (2) ‘Candidatus Phytoplasma mali’, ‘Ca. P. pyri’ and ‘Ca. P. prunorum’

Specific scope

This Standard describes a diagnostic protocol for ‘Candidatus Phytoplasma mali’, ‘Ca. P. pyri’ and ‘Ca. P. prunorum’. This Standard should be used in conjunction with PM 7/76 Use of EPPO diagnostic protocols

Specific approval and amendment

Approved as PM 7/62 Candidatus Phytoplasma mali and PM 7/63 Ca. P. pyri in 2006. Revised in 2017‐02 as a single Standard as PM 7/62 (2) with the addition of ‘Ca. P. prunorum’.     

Metabolism of amitrole in apple: II. Bound residues from mature fruits

Significant radioactivity detected in mature fruits, harvested from apple trees (Malus domestica Borkh., cv. ‘Golden Delicious’ and ‘Gloster’) that were soiltreated with [3,5-¹⁴C]amitrole, remained in the insoluble plant material after exhaustive extraction. These bound residues were solubilized with a mixture of pectinases and cellulases. Thus, separation and characterization of carbohydrates and xenobiotic moieties released during this procedure became possible. A part of the radiolabel was incorporated into natural products, indicating degradation of the applied amitrole and reassimilation of [¹⁴C] carbon dioxide.     

Inheritance of apple proliferation resistance by parental lines of apomictic <Emphasis Type="Italic">Malus sieboldii</Emphasis> as donor of resistance in rootstock breeding

To study inheritance of Malus sieboldii-derived apple proliferation resistance, 14 cross combinations were performed with the tetraploid apomictic M. sieboldii and first and second generation parental lines as donor of resistance and Malus x domestica scion cultivars and apple rootstocks as donor of pomological traits. In the progeny examined mainly three classes were present consisting of mother-like plants with the allele composition of the maternal apomict (ML), hybrids based on fertilization of an unreduced egg cell (hybrid I), and fully recombinant plants (hybrid II). Two-year screening of inoculated plants in the nursery revealed that progeny classes ML and H I responded similarly to infection and that about half of the progeny showed satisfactory resistance. No appropriate resistance was identified in progeny class H II. This might be due to the fact that in fully recombinant offspring M. sieboldii haplotypes have been reduced from 4n to 1-2n or were entirely lost. Following nursery-growing, promising trees were evaluated for six more years in the orchard. Nearly all of them showed satisfactory resistance but were mostly less productive and more vigorous than trees on clonal standard rootstock M9. However, mainly among the offspring of progeny 4608 × M9, resistant genotypes were identified showing pomological properties similar to M9.     

Effects of stolbur phytoplasma infection on DNA methylation processes in tomato plants

DNA methylation was investigated as a possible mechanism for regulation of floral gene expression in stolbur phytoplasma‐infected tomato buds. Expression of methylase and demethylase genes was found to be globally down‐regulated in tomato plants infected with stolbur isolate PO, but not in those infected with isolate C. These results are consistent with the finding that SlDEF, a gene orthologous to arabidopsis APETALA3 which is involved in petal formation, was down‐regulated in stolbur PO‐infected buds and remained unaffected in stolbur C‐infected buds, and with the fact that the two stolbur phytoplasma isolates C and PO induce distinct symptoms. Because of variations between the different cell‐types of the flower buds, the DNA methylation status of SlDEF could not be clearly established. However, the finding that treatment of stolbur PO‐infected plants with 5‐azacytidine partially restored SlDEF gene expression strongly suggests that DNA methylation is involved in down‐regulation of floral development genes in stolbur PO‐infected tomatoes.     

Differentially-regulated defence genes in Malus domestica during phytoplasma infection and recovery

To improve knowledge about plant/phytoplasma interactions and, in particular, about the ‘recovery’ phenomenon in previously-infected plants, we investigated and compared expression levels of several defence-related genes (four pathogenesis-related proteins and three jasmonate-pathway marker enzymes) in apple plants showing different states of health: vigorous (healthy), phytoplasma-infected, and recovered. Real Time-PCR analyses demonstrated that genes are differentially expressed in apple leaf tissue according to the plants’ state of health. Malus domestica Pathogenesis-Related protein (MdPR) 1, MdPR 2 and MdPR 5 were significantly induced in leaves of diseased and symptomatic plants compared to leaves of those plants that were healthy or recovered. On the other hand, levels of all the jasmonate (JA)-pathway marker genes that we selected for this study, were up-regulated in the leaves of recovered plants compared to the diseased ones. In conclusion, our study demonstrated that two different sets of defence genes are involved in the interactions between apple plants and ‘Candidatus Phytoplasma mali’ (‘Ca. P. mali’) and that these genes are differentially expressed during phytoplasma infection or recovery.     

Transmission of ‘Candidatus Phytoplasma pyri’ by naturally infected Cacopsylla pyri to peach,an approach to the epidemiology of peach yellow leaf roll (PYLR) in Spain

Peach orchards in the northeast of Spain were severely affected in 2012 by a previously unreported disease in this area. The symptoms included early reddening, leaf curling, decline, abnormal fruits, and in some cases death of the peach trees. All the infected peach samples were positive for ‘Candidatus Phytoplasma pyri’, but none were infected by the ‘Ca. Phytoplasma prunorum’. In this work, potential vectors able to transmit ‘Ca. Phytoplasma pyri’ from pear to peach and between peach trees were studied and their infective potential was analysed at different times of the year. Transmission trials of the phytoplasma with potential vectors to an artificial feeding medium for insects and to healthy peach trees were conducted. Additionally, isolated phytoplasmas were genetically characterized to determine which isolates were able to infect peach trees. Results showed that the only insect species captured inside peach plots that was a carrier of the ‘Ca. Phytoplasma pyri’ phytoplasma was Cacopsylla pyri. Other insect species captured and known to be phytoplasma transmitters were present in very low numbers, and were not infected with ‘Ca. Phytoplasma pyri’ phytoplasma. A total of 1928 individuals of C. pyri were captured in the peach orchards, of which around 49% were phytoplasma carriers. All the peach trees exposed to C. pyri in 2014, and 65% in 2015, were infected by ‘Ca. Phytoplasma pyri’ 1 year after exposure, showing that this species is able to transmit the phytoplasma to peach. Molecular characterization showed that some genotypes are preferentially determined in peach.     

Kerala wilt disease phytoplasma: Phylogenetic analysis and identification of a vector, Proutista moesta

Kerala wilt disease of coconut palm is a major threat of coconut production in Kerala caused by phytoplasma. The genomic DNA purified from the insect tissues of Proutista moesta (PM) and Stephanitis typica (ST) was subjected to PCR assay using the primer combination P1/P6, P1/P7 and P4/P7. The amplified products resolved a prominent band of 650 bp for the universal primer P4/P7 and no bands were noticed for the primer pairs P1/P6 and P1/P7 combination. Since P4/P7 amplifies the 16S–23S intergenic spacer region of 16SrRNA gene, the PCR product 650 bp of the insect PM indicate the phytoplasma DNA. The presence of 650 bp for the primer P4/P7 in the genomic DNA isolated from P. moesta indicates the vectoral ability of the insect. No sign of amplification was noticed in the case of ST for the three sets of primers suggesting the inability of this insect as vector. The amplified product 650 bp from the genomic DNA of KWD palms as well as the insect tissues of P. moesta was gel purified and sequenced. The sequential similarity of 650 bp of both KWD phytoplasma and the insect phytoplasma supports the transmission of phytoplasma through the vector PM. Moreover, the sequence of 650 bp was compared with other sequences of 26 coconut phytoplasmas so far reported internationally and a cladogram was prepared for determining the phylogenetic status. It is obvious from the cladogram that the KWD disease phytoplasma is evolutionarily closest to coconut phytoplasma of coconut lethal yellowing of Mexican palms within the group 16SrIV. Phylogenetically, KWD phytoplasma is grouped in the new subgroup 16SrIV-C subsequent to the groups 16SrIV-A and 16SrIV-B for Mexican coconut lethal yellowing and Tanzanian coconut lethal decline, respectively. The restriction enzyme analysis of the PCR product 650 bp using the enzymes AluI, BclI, HindIII and RsaI further supports the phytoplasmic nature of DNA. This data records the first finding of the vector of Kerala wilt disease by detecting KWD phytoplasma in insect tissue of PM by PCR based methods. Moreover, the study reveals the phylogenetic status of KWD phytoplasma compared to other coconut phytoplasmas internationally.     

Increased plant tolerance against chrysanthemum yellows phytoplasma (‘Candidatus Phytoplasma asteris’) following double inoculation with Glomus mosseae BEG12 and Pseudomonas putida S1Pf1Rif

The aim of this work was to assess the effects of a combined inoculum of a rhizobacterium and an arbuscular mycorrhizal (AM) fungus on plant responses to phytoplasma infection, and on phytoplasma multiplication and viability in Chrysanthemum carinatum plants infected by chrysanthemum yellows phytoplasma (CY). Combined inoculation with Glomus mosseae BEG12 and Pseudomonas putida S1Pf1Rif resulted in some resistance to phytoplasma infection (about 30%), delayed symptom expression in nonresistant plants, improved growth of the aerial part of the infected plants (+68·1%), and altered root morphology (root tip number: +49·9%; branching degree: +82·8%). Combined inoculation with the two beneficial microorganisms did not alter CY multiplication and viability. In inoculated and infected plants, phytoplasma morphology was typical of senescent cells. A more active and efficient root system in double‐inoculated plants probably mediated the effects of the two rhizospheric microorganisms in the infected plants. The practical application of rhizospheric microorganisms for mitigating phytoplasma damage, following evaluation under field conditions, represents an additional tool for the integrated management of phytoplasmosis.     

Sensitive Detection of a Phytoplasma Associated with Little Leaf Symptoms in Withania somnifera

Withania somnifera is an important medicinal plant native to the Indian-sub continent. Owing to the presence of a number of precious alkaloids, flavonoids and withanolides, it is widely used in the Indian and African systems of medicines. It is severely affected by phytoplasma present in the sieve tubes of phloem. With a view to micropropagate phytoplasma-free W. somnifera plants, an efficient and effective nested PCR-based system was developed for detection of associated phytoplasmas. Universal primers, designed from the 16S rDNA sequences of phytoplasmas, were applied in direct/nested-PCR. Total DNA extracts from leaf tissues of 33 suspected symptomatic and 11 non-symptomatic plants were subjected to direct PCR. The direct PCR products were subsequently employed as templates in nested PCR. The nested PCR could reamplify direct PCR products yielding a DNA fragment of 1.4 kb. A phytoplasma was detected in all the diseased plants and not from the healthy looking plants. Further, it was sensitive enough to amplify phytoplasma DNA obtained from crude DNA diluted up to 2500 times from naturally infected plants and also from various stages of in vitro-propagated diseased plants. Identical restriction fragment polymorphism enzyme profiles were obtained following restriction enzyme digestion of nested PCR products, obtained from five different plants, by EcoRI, AluI and RsaI restriction endonucleases. The developed nested PCR based system should facilitate indexing of the phytoplasma in different stages of in vitro-generated plants and probably identification of, as yet unknown, hosts and vectors of phytoplasma associated with phytoplasma disease of W. somnifera.     

High diversity,expanding populations and purifying selection in phytoplasmas causing coconut lethal yellowing in Mozambique

In this study, the putative phytoplasma species causing coconut lethal yellowing disease in Mozambique and Tanzania were characterized. The 16S rRNA and secA genes were sequenced. Phylogenetic analysis revealed that Mozambican coconut phytoplasmas belong to three different types: ‘Candidatus Phytoplasma palmicola’ 16SrXXII‐A, a second strain that was previously isolated in Tanzania and Kenya (16SrIV‐C), and a third strain that was different from all known lethal yellowing phytoplasma species. The third strain potentially represents a novel species and is closely related to pine phytoplasma. Co‐infection with ‘Ca. Phytoplasma pini’‐related and ‘Ca. Phytoplasma palmicola’ 16SrXXII‐A strains was observed. Furthermore, sequence variation in ‘Ca. Phytoplasma palmicola’ at the population level was consistent with purifying selection and population expansion.     

Metabolism of amitrole in apple: III. Model systems

Excised shoots from apple trees and cell suspension cultures were used as model systems to study the metabolism of [3,5-¹⁴C]amitrole in Malus domestica Borkh. Significant differences in the metabolism of the compound applied were observed with excised shoots, cultured cells and whole apple trees. The major metabolite in excised shoots was aminotriazolylalanine which occurred both in the free form and as conjugates. The major metabolite from whole plants. triazolylalanine, was detected in shoots in minor amounts only. In cell suspension cultures, the type of metabolism strongly depended on the concentration of amitrole when initially applied. At 10 ^?3 m or lower, mainly aminotriazolylalanine was formed. Depending on the concentration of the active ingredient, this metabolite predominantly occurred in free form or as glycosides. At concentrations above 5 × 10^?4 M a new metabolite, 3,5-dihydroxytriazole, was detected which was the only metabolite found at 5 × 10^?3M. Significant amounts of nonmetabolized amitrole remained in the medium.