Phytoplasmas: An Introduction.

Phytoplasmas are among the most recently discovered plant pathogens. They are wall-less prokaryotes restricted to phloem tissue, associated with diseases affecting several hundred plant species. The impact of phytoplasma diseases on agriculture is impressive and, at the present day, no effective curative strategy has been developed. The availability of rapid and sensitive techniques for phytoplasma detection as well as the possibility to study their relationship with the host plants is a prerequisite for the management of phytoplasma-associated diseases.

What Slows Down Phytoplasma Proliferation? Speculations on the Involvement of AtSEOR2 Protein in Plant Defence Signalling.

Considering the crude methods used to control phytoplasma diseases, a deeper knowledge on the defence mechanisms recruited by the plant to face phytoplasma invasion is required. Recently, we demonstrated that Arabidopsis mutants lacking AtSEOR1 gene showed a low phytoplasma titre. In wild type plants AtSEOR1 and AtSEOR2 are tied in filamentous proteins. Knockout of the AtSEOR1 gene may pave the way for an involvement of free AtSEOR2 proteins in defence mechanisms. Among the proteins conferring resistance against pathogenic bacteria, AtRPM1-interacting protein has been found to interact with AtSEOR2 in a high-quality, matrix-based yeast-two hybrid assay. For this reason, we investigated the expression levels of Arabidopsis AtRIN4, and the associated AtRPM1 and AtRPS2 genes in healthy and Chrysanthemum yellows-infected wild-type and Atseor1ko lines.

Combined microscopy and molecular analyses show phloem occlusions and cell wall modifications in tomato leaves in response to 'Candidatus Phytoplasma solani'.

Callose deposition, phloem-protein conformational changes and cell wall thickening are calcium-mediated occlusions occurring in the plant sieve elements in response to different biotic and abiotic stresses. However, the significance of these structures in plant-phytoplasma interactions requires in-depth investigations. We adopted a novel integrated approach, based on the combined use of microscopic and molecular analyses, to investigate the structural modifications induced in tomato leaf tissues in presence of phytoplasmas, focusing on vascular bundles and on the occlusion structures. Phloem hyperplasia and string-like arrangement of xylem vessels were found in infected vascular tissue. The diverse occlusion structures were differentially modulated in the phloem in response to phytoplasma infection. Callose amount was higher in midribs from infected plants than in healthy ones. Callose was observed at sieve plates but not at pore-plasmodesma units. A putative callose synthase gene encoding a protein with high similarity to Arabidopsis CalS7, responsible for callose deposition at sieve plates, was upregulated in symptomatic leaves, indicating a modulation in the response to stolbur infection. P-proteins showed configuration changes in infected sieve elements, exhibiting condensation of the filaments. The transcripts for a putative P-protein 2 and a sieve element occlusion-related protein were localized in the phloem but only the first one was modulated in the infected tissues.

Acquired Tolerance in Apricot Plants that Stably Recovered from European Stone Fruit Yellows.

European stone fruit yellows (ESFY) is one of the most destructive phytoplasma diseases of plum, apricot, and peach in Europe. Conventional preventive defense strategies have been ineffective. Because apricot cultivars with innate-constitutive resistance against ESFY are not available, the aim of this more than 20-year-long study was to seek acquired resistance or tolerance. In the first experiment, we surveyed an orchard with seven apricot cultivars for 12 years in an area of northern Italy with a high rate of natural occurrence of ESFY. Of the diseased plants, a few (8.7%) became completely symptomless but retained the phytoplasma, as confirmed by polymerase chain reaction (PCR). In the second experiment, we grafted buds from two stably recovered plants and from two nonrecovered plants onto 'Rubira' peach. Over the next 9 years in an orchard with a high rate of natural infection, 93.0% of the "nonrecovered clones" became diseased but only 1.5% of the plants grafted with the two "recovered clones" developed ESFY symptoms. According to PCR analyses, all of the exposed test plants were ESFY-infected, whether they were derived from recovered or nonrecovered mothers. This could indicate that epigenetic changes occurred in recovered plants due to a graft-transmissible memory. Based on the results attained from the two described experiments, we propose that an acquired tolerance that occurred in stably recovered apricot trees was graft transmitted from two tolerant apricot clones. In contrast, we did not demonstrate a cross-protection process based on protectant avirulent phytoplasma strains that suppress severe strains.

Interactions between 'Candidatus Phytoplasma mali' and the apple endophyte Epicoccum nigrum in Catharanthus roseus plants.

AIMS: We investigated the ultrastructural and molecular interactions between 'Candidatus Phytoplasma mali' and the apple endophyte Epicoccum nigrum in the experimental host Catharanthus roseus to determine whether inoculation of endophyte could trigger defence reactions in the host. METHODS AND RESULTS: Apple proliferation (AP) symptom severity was evaluated in AP-grafted plants that were treated by E. nigrum and compared with untreated controls. Phytoplasma concentration was quantified by real-time PCR in treated and untreated plants. Ultrastructural observations revealed that in endophyte-treated periwinkles, modifications to phytoplasmas, such as irregular shape and cytoplasm confined to the periphery of the cell, and plant cytological changes, such as abundant callose depositions and P-protein aggregations in the sieve elements, occurred. AP-grafted plants that were treated by the endophyte (E. nigrum) showed a reduction in symptom severity; in particular, flowers appeared normal in shape and size, when compared with uninfected controls. Real-time PCR indicated that phytoplasma concentration in AP-grafted plants treated with E. nigrum was about 2·8 times lower than that in untreated ones. CONCLUSIONS: These results demonstrated that the inoculation with E. nigrum influenced phytoplasma infection in C. roseus plants; plant ultrastructural modifications allowed us to hypothesize an enhancing host defence response. SIGNIFICANCE AND IMPACT OF THE STUDY: At present, curative protocols against this phytoplasma are not available. Alternative approaches are thus required to reduce disease spread. Our study might represent a first step in the clarification of plant-phytoplasma-endophyte relationships to find possible strategies for the control of phytoplasma diseases.

Phloem cytochemical modification and gene expression following the recovery of apple plants from apple proliferation disease.

Recovery of apple trees from apple proliferation was studied by combining ultrastructural, cytochemical, and gene expression analyses to possibly reveal changes linked to recovery-associated resistance. When compared with either healthy or visibly diseased plants, recovered apple trees showed abnormal callose and phloem-protein accumulation in their leaf phloem. Although cytochemical localization detected Ca(2+) ions in the phloem of all the three plant groups, Ca(2+) concentration was remarkably higher in the phloem cytosol of recovered trees. The expression patterns of five genes encoding callose synthase and of four genes encoding phloem proteins were analyzed by quantitative real-time reverse transcription-polymerase chain reaction. In comparison to both healthy and diseased plants, four of the above nine genes were remarkably up-regulated in recovered trees. As in infected apple trees, phytoplasma disappear from the crown during winter, but persist in the roots, and it is suggested that callose synthesis/deposition and phloem-protein plugging of the sieve tubes would form physical barriers preventing the recolonization of the crown during the following spring. Since callose deposition and phloem-protein aggregation are both Ca(2+)-dependent processes, the present results suggest that an inward flux of Ca(2+) across the phloem plasma membrane could act as a signal for activating defense reactions leading to recovery in phytoplasma-infected apple trees.

DNA-Dependent Detection of the Grapevine Fungal Endophytes Aureobasidium pullulans and Epicoccum nigrum.

Aureobasidium pullulans and Epicoccum nigrum are frequently reported as endophytes of various crops, including grapevine (Vitis vinifera). Because of their potential role as biological control agents against grapevine pathogens, we examined the occurrence of A. pullulans and E. nigrum in two grapevine varieties (Merlot and Prosecco) in Italian vineyards where spontaneous recovery from phytoplasma disease is recurrent. Species-specific primers for A. pullulans and two genetically distinct strains of E. nigrum were designed in variable regions of ITS1 and ITS2. Primer specificity was confirmed by polymerase chain reaction using purified DNA from other fungal endophytes that are usually encountered during isolation attempts from grapevine tissues and from several other strains of A. pullulans and E. nigrum isolated from other sources. In order to determine the occurrence of the two endophytes in grapevine plants, DNA was extracted from shoots of 44 grapevines collected in six vineyards from different localities of northeast Italy. Both endophytes were detected and their identity was confirmed by restriction fragment length polymorphism (RFLP) patterns obtained from reference strains. RFLP analyses confirmed the presence of two E. nigrum strains belonging to different RFLP groups in grapevine. The molecular methods described allowed a sensitive, specific, and reliable identification of the two endophytes in grapevine.

First and second line mechanisms of cadmium detoxification in the lichen photobiont Trebouxia impressa (Chlorophyta).

"First line" defence mechanisms, such as phytochelatin biosynthesis, and "second line" mechanisms, such as stress protein induction, were investigated in cadmium-exposed cells of Trebouxia impressa Ahmadjian, a green microalgal species that is a common photobiont of the lichen Physcia adscendens (Fr.) H. Olivier. When T. impressa cells were exposed to 0, 9 and 18 microM Cd for 6, 18 and 48 h, glutathione and phytochelatins efficiently protected the cells against Cd damage. By contrast, the highest Cd concentration (36 microM) at the longest exposure-time (48 h) caused marked drops in glutathione and phytochelatin content, several types of ultrastructural damage, and decreases in cell density and total chlorophyll concentration. In this case, induction of stress proteins was observed, but only long after the induction of phytochelatins. Thus, stress proteins could represent a "second line" mechanism to counteract Cd stress, activated when there is a decline in the "first line" mechanism of Cd detoxification given by phytochelatins.

Antifungal activity of diketopiperazines extracted from Alternaria alternata against Plasmopara viticola: an ultrastructural study.

Three dipeptides, belonging to the family of diketopiperazines (DKPs), were extracted from broth culture of the grapevine endophyte Alternaria alternata, and were tested against Plasmopara viticola on leaves of grapevine plants grown in greenhouse. DKPs, used at different concentrations (10(-3), 10(-4), 10(-5) and 10(-6)M) both singularly and in mixtures, demonstrated real effectiveness in inhibiting P. viticola sporulation when applied 2 or 24h after pathogen inoculation. Moreover, no necrotic lesions or other phytotoxicity symptoms were observed on DKP-treated grapevine leaf tissues. Ultrastructural analysis performed on grapevine leaf tissues revealed that the DKPs used singularly and in mixture, at above reported concentrations, did not cause leaf tissue damages. By contrast, hyphae of P. viticola exhibited marked structural changes, similar to those induced by the endophyte A. alternata. This demonstrates the involvement of these metabolites in the relationship of P. viticola and the endophyte. Further experimental trials will be carried out in the next future in order to test the effectiveness of these molecules also under field conditions, and to better understand the mechanism of action involved in the pathogen inhibition.

Inhibition of Sporulation and Ultrastructural Alterations of Grapevine Downy Mildew by the Endophytic Fungus Alternaria alternata.

ABSTRACT One hundred twenty-six endophytic microorganisms isolated from grapevine leaves showing anomalous symptoms of downy mildew were tested on grapevine leaf disks as biocontrol agents against Plasmopara viticola. Among the 126 microorganisms, only five fungal isolates completely inhibited the sporulation of P. viticola; all of them were identified as Alternaria alternata. Ultrastructural analyses were carried out by transmission electron microscopy to observe cellular interactions between P. viticola and A. alternata in the grapevine leaf tissue. Cytological observations indicated that, even without close contact with A. alternata, the P. viticola mycelium showed severe ultrastructural alterations, such as the presence of enlarged vacuoles or vacuoles containing electron-dense precipitates. Haustoria appeared necrotic and irregularly shaped or were enclosed in callose-like substances. Therefore, a toxic action of A. alternata against P. viticola was hypothesized. To examine the production of toxic low-molecular-weight metabolites by A. alternata, we analyzed the fungal liquid culture by thin layer chromatography and proton magnetic resonance spectroscopy. The main low-molecular-weight metabolites produced by the endophyte were three diketopiperazines: cyclo(l-phenylalanine-trans-4-hydroxy-l-proline), cyclo(l-leucine-trans-4-hydroxy-l-proline), and cyclo(l-alanine-trans-4-hydroxy-l-proline). When applied at different concentrations to both grapevine leaf disks and greenhouse plants, a mixture of the three diketopiperazines was very efficacious in limiting P. viticola sporulation.

Ultrastructural analysis of Vitis vinifera leaf tissues showing atypical symptoms of Plasmopara viticola.

In an abandoned farm in Tuscany a year by year regression of downy mildew disease on grapevines was observed and a decrease in virulence as well as vigor and fertility of the causal fungus, Plasmopara viticola. Anomalous spots of the fungus (i.e. atypical coloration of leaves or mosaic) on leaf tissues of a sensitive Vitis vinifera grapevine were observed. The anomalous symptoms were often associated with the typical 'oil spots' and were present under environmental conditions favourable for a normal development of the disease. An ultrastructural study was carried out on leaf tissues of grapevine plants aimed at clarifying the cause of this phenomenon and detecting whether there were alterations in P. viticola mycelium and endophytes present. ELISA was also performed to check the presence of grapevine viruses in the plants. TEM results demonstrated that characteristic P. viticola was present in leaf samples showing oil spots, while, both the fungus and the host tissues showed cytological alterations in leaves with mosaic symptoms. Finally, hyphae were absent in leaf tissues without downy mildew spots, but showing severe ultrastructural modifications. Several plant virus infections were found in these grapevines. Literature reports that the development and sporulation of some phytopathogenic fungi inside their hosts can be limited by virus infections. Further experimental approaches are required to determine if resistance to P. viticola can be induced by viral infections in grapevines.

Detection of apoptosis-inducing factor in involuting mammary tissue by immunoelectron microscopy.

Immunoelectron microscopy was used to study the subcellular localisation of apoptosis-inducing factor (AIF) in involuting bovine mammary tissue. AIF was detected using a polyclonal antibody and secondary anti-rabbit antibody conjugated to colloidal gold particles under optimised conditions. The polyclonal antibody appeared specific for the bovine antigen and immunocytological examination identified specific localisation of AIF in mitochondria, cytoplasm and nucleus of mammary epithelial cells in involuting mammary tissue, suggesting a subcellular translocation in cells undergoing apoptosis.

Catharanthus roseus L. plants and explants infected with phytoplasmas: alkaloid production and structural observations.

The results of several experiments concerning the presence and composition of alkaloids in different tissues (stems, leaves, roots) of Catharanthus roseus L. plants and explants, healthy and infected by clover phyllody phytoplasmas, are reported. The alkaloids extracted and determined by the reverse phase high-pressure liquid chromatography were vindoline, ajmalicine, serpentine, vinblastine, and vincristine. The total alkaloid concentration was higher in infected plants than in the controls, in particular the increase of vinblastine in infected roots was very significant. The ultrastructural observations of infected roots showed alterations of the cell walls and of the nuclei. These results demonstrate that phytoplasmas, detected in all infected tissues by light fluorescence and transmission electron microscopy, play an important role on secondary metabolism of the diseased plants, modifying both the total content of alkaloids and their ratio.

Recovery in apple trees infected with the apple proliferation phytoplasma: an ultrastructural and biochemical study.

ABSTRACT Localization of hydrogen peroxide (H(2)O(2)) and the roles of peroxidases, malondialdehyde, and reduced glutathione in three apple cultivars were compared in healthy trees, trees infected with apple proliferation phytoplasma (APP), and trees that had recovered from the infection. In recovered apple trees, symptoms of the disease and the pathogen had disappeared from the canopy, but phytoplasmas remained in the roots. H(2)O(2) was detected cytochemically by its reaction with cerium chloride to produce electron-dense deposits of cerium perhydroxides.H(2)O(2) occurred in the plasmalemma of the phloem of leaves of recovered apple trees, but not in healthy or APP-infected leaves. In all cultivars, the peroxidase activity detected in tissue from APP-diseased trees was greater than or equal to that of tissue from recovered trees, which equaled or exceeded that of tissue from healthy trees, at two sampling times (May and September). In contrast, the glutathione content of leaves decreased in the reverse order. More malondialdehyde was observed in leaves from recovered trees than in leaves from healthy or APP-infected trees in three of six cultivar-date combinations; in the other three combinations, the malondialdehyde contents of leaves from healthy, infected, and recovered trees were not significantly different from one another. The results suggest that some components of the oxidant-scavenging system in recovered leaves are not very active, leading to an overproduction of H(2)O(2) and, possibly, to a membrane lipid peroxidation.The production of H(2)O(2) appears to be involved in counteracting pathogen virulence.

Cytological modifications in maize plants infected by barley yellow dwarf virus and maize dwarf mosaic virus.

Three inbred lines of maize (33-16, MO17 and B73) differing in their susceptibility to Barley yellow dwarf virus and Maize dwarf mosaic virus were studied to compare the ultrastructural modifications induced by the two viruses in leaf tissues of different age. The results demonstrate that the alterations induced by the two viruses in the different maize lines could depend on the particular line tested.

Histopathology and polyphenol content in plants infected by phytoplasmas.

The alterations of cell walls and the localization of several compounds such as polyphenols, suberin, lignin, in plum and apple plants infected with plum leptonecrosis (PLN) and apple proliferation (AP) phytoplasmas respectively, were investigated. Catharanthus roseus plants, infected with AP or PLN were also studied. The 4,6-diamidino-2-phenylindole (DAPI) test and transmission electron microscopy showed the presence of phytoplasmas in all infected plants. Specific histological stainings for cutinized/suberinized cell walls, tannin deposits and vacuolar polyphenol inclusions, performed on leaf and stem tissues, revealed an increase of these substances in infected plum and apple plants. No differences occurred in C. roseus. Total polyphenol analysis confirmed a strong increase (3-fold) in the polyphenol content in infected tissues, particularly in plum leaves. From the data obtained it appears that polyphenols can be considered as defence-related metabolites in plum and apple plants infected by phytoplasmas. Further investigations are necessary to determine whether these compounds play a specific role in the development of all phytoplasma/host interactions and in the defence-related processes.