Sieve element biology provides leads for research on phytoplasma lifestyle in plant hosts.

Phytoplasmas reside exclusively in sieve tubes, tubular arrays of sieve element-companion cell complexes. Hence, the cell biology of sieve elements may reveal (ultra)structural and functional conditions that are of significance for survival, propagation, colonization, and effector spread of phytoplasmas. Electron microscopic images suggest that sieve elements offer facilities for mobile and stationary stages in phytoplasma movement. Stationary stages may enable phytoplasmas to interact closely with diverse sieve element compartments. The unique, reduced sieve element outfit requires permanent support by companion cells. This notion implies a future focus on the molecular biology of companion cells to understand the sieve element-phytoplasma inter-relationship. Supply of macromolecules by companion cells is channelled via specialized symplasmic connections. Ca2+-mediated gating of symplasmic corridors is decisive for the communication within and beyond the sieve element-companion cell complex and for the dissemination of phytoplasma effectors. Thus, Ca2+ homeostasis, which affects sieve element Ca2+ signatures and induces a range of modifications, is a key issue during phytoplasma infection. The exceptional physical and chemical environment in sieve elements seems an essential, though not the only factor for phytoplasma survival.

Application of laser microdissection to study phytoplasma site-specific gene expression in the model plant Arabidopsis thaliana.

Many aspects of plant diseases caused by phytoplasmas are still unknown, as these pathogens are phloem restricted, uncultivable wall-less bacteria and must be studied always in association with their host. Phytoplasma transcripts are strongly underrepresented within host tissues and this poses problems for gene expression analyses. In this study, a procedure was established to infect the model plant Arabidopsis thaliana with the phytoplasma Flavescence dorée, a serious threat to European viticulture. Rates of phytoplasma infective insects and transmission efficiency to A. thaliana as well as pathogen loads were measured in different tissues of infected A. thaliana plants, and modification of phloem cell ultrastructure was observed in infected plant tissues at microscopic level. Moreover, a protocol for the application of laser microdissection to analyze plant and phytoplasma gene expression profiles in the specific colonized tissue was designed. The procedure allowed a good preservation of the plant tissue anatomy. Results showed that the extracted RNA was suitable for qualitative and quantitative RT-PCR, since both plant and pathogen transcripts, either abundant or rare ones, could be detected without any pre-amplification step. The combined use of laser microdissection approach and A. thaliana to study phytoplasmas opens the way to exploit biological, molecular and bioinformatic tools available for the model plant and to elucidate key pathways of the infection mechanisms of these important plant pathogen.

Looking inside phytoplasma-infected sieve elements: A combined microscopy approach using Arabidopsis thaliana as a model plant.

Phytoplasmas are phloem-inhabiting plant pathogens that affect over one thousand plant species, representing a severe threat to agriculture. The absence of an effective curative strategy and the economic importance of many affected crops make a priority of studying how plants respond to phytoplasma infection. Nevertheless, the study of phytoplasmas has been hindered by the extreme difficulty of culturing them in vitro and by impediments to natural host plant surveys such as low phytoplasma titre, long plant life cycle and poor knowledge of natural host-plant biology. Stating correspondence between macroscopic symptoms of phytoplasma infected Arabidopsis thaliana and those observed in natural host plants, over the last decade some authors have started to use this plant as a model for studying phytoplasma-plant interactions. Nevertheless, the morphological and ultrastructural modifications occurring in A. thaliana tissues following phytoplasma infection have never been described in detail. In this work, we adopted a combined-microscopy approach to verify if A. thaliana can be considered a reliable model for the study of phytoplasma-plant interactions at the microscopical level. The consistent presence of phytoplasma in infected phloem allowed detailed study of the infection process and the relationship established by phytoplasmas with different components of the sieve elements. In infected A. thaliana, phytoplasmas induced strong disturbances of host plant development that were mainly due to phloem disorganization and impairment. Light microscopy showed collapse, necrosis and hyperplasia of phloem cells. TEM observations of sieve elements identified two common plant-responses to phytoplasma infection: phloem protein agglutination and callose deposition.

OHMS**: Phytoplasmas dictate changes in sieve-element ultrastructure to accommodate their requirements for nutrition, multiplication and translocation.

Phytoplasmas are among the most recently discovered plant pathogenic microorganisms so, many traits of the interactions with host plants and insect vectors are still unclear and need to be investigated. At now, it is impossible to determine the precise sequences leading to the onset of the relationship with the plant host cell. It is still unclear how phytoplasmas, located in the phloem sieve elements, exploit host cell to draw nutrition for their metabolism, growth and multiplication. In this work, basing on microscopical observations, we give insight about the structural interactions established by phytoplasmas and the sieve element plasma membrane, cytoskeleton, sieve endoplasmic reticulum, speculating about a possible functional role.

Visualization of phytoplasmas using electron microscopy.

The use of electron microscopy, both transmission and scanning, provides reliable and accurate methods for detecting phytoplasmas in plants. Our understanding of these pathogens, their morphology, development, and intracellular location in plants and insect vectors has been greatly increased through the use of these instruments. Development of techniques such as immunolabeling, cryofixation with freeze substitution or plunge freezing with direct transfer to the microscope stage, together with advances in instrumentation is enabling us to study these pathogens under conditions close to their native state. The visualization of fine detail and ultrastructure, using modern and established techniques, can only be appreciated by the magnification and spatial resolution offered in the electron microscopes. Now that the full sequencing of four phytoplasma genomes (to date) has been achieved, electron microscopy can play an important role in identifying and understanding specific gene functions.

Effects of Pseudomonas putida S1Pf1Rif against chrysanthemum yellows phytoplasma infection.

Phytoplasmas cause damage on a number of plant species leading to relevant economical loss. Up to now, strategies to limit their spread led to only partial success. In this context, the use of plant-beneficial bacteria to control phytoplasmas has never been explored. The aim of this work was to assess the effect of Pseudomonas putida S1Pf1Rif against chrysanthemum yellows phytoplasma (CYP) infection of daisy. Plant biomass, root architecture, symptom severity, phytoplasma titer, and viability were evaluated in inoculated and control plants. CYP reduced plant growth and root development. Although the phytoplasma titer in young apical leaves was not affected by inoculation with S1Pf1Rif, the pseudomonad improved plant growth of CYP-infected plants. Whereas CYP titer increased over time in uninoculated plants, its viability decreased, regardless of the presence of P. putida S1Pf1Rif. Finally, phytoplasma cells in fully developed leaves of CYP-infected plants inoculated with S1Pf1Rif often appeared degenerated. Overall, our results indicate that P. putida S1Pf1Rif is able to alleviate the disease, although it does not affect the presence of viable phytoplasmas in young, developing leaves of the infected plants.

Phytoplasma associated with witches'-broom disease of Ulmus minor MILL . in the Czech Republic: Electron microscopy and molecular characterization.

Visual inspections of elm trees in south Moravia in 1997-2007 revealed a rare occurrence of plants with smaller and cowl-forming leaves on some twigs, i.e. a feature resembling witches'-broom disease observed on the end of twigs. The presence of phytoplasma-like bodies was observed by transmission electron microscopy of phloem tissue. On the other hand, no phytoplasmas were found in asymptomatic trees. Nucleic acids extracted from these plants were used in nested-PCR assays with primers amplifying 16S rRNA sequences specific for phytoplasmas. Sequence analyses of the 16S-23S ribosomal operon (1852 bp) allowed for the classification of the detected phytoplasmas in the elm yellows group, but its position remained on the boundary of the 16SrV-A and 16SrV-C ribosomal subgroups. Sequence analyses of the ribosomal protein of the rpl22-rps3 and secY genes lead to further classification and revealed the phytoplasmas' affiliations to the 'Candidates Phytoplasma ulmi'. Some exceptions in unique oligonucleotide sequences defined for 'Ca. Phytoplasma ulmi' were found in the Czech isolate. This is the northernmost confirmed occurrence of phytoplasma on elm trees within Europe.

A phytoplasma related to 'Candidatus phytoplasma asteri' detected in citrus showing Huanglongbing (yellow shoot disease) symptoms in Guangdong, P. R. China.

Citrus huanglongbing (HLB) or yellow shoot disease (i.e., greening disease) is highly destructive to citrus production worldwide. Understanding the etiology of HLB is critical for managing the disease. HLB is currently associated with infection by 'Candidatus Liberibacter spp.' around the world, including China. However, Koch's postulates have not been fulfilled. In addition, other plant pathogens also may be involved in HLB. In a survey performed in Guangdong Province, P. R. China in 2006 and 2007, 141 citrus samples showing typical symptoms of HLB from 11 different cities were collected. Polymerase chain reaction (PCR) using phytoplasma-specific primer sets fU5/rU3 nested with primer set P1/P7 identified 110 (78.0%) positive samples. A 1,785-bp amplicon was obtained with primer set P1/P7. Analysis showed a 100% identity of this sequence in the region of 16S rDNA and 16S-23S rRNA intergenic transcribed spacer to three strains of 'Candidatus Phytoplasma asteri' (onion yellows [Japan], aster yellows 'watercress' [Hawaii], and valeriana yellows [Lithuania]). Of the 141 samples, 89 (63.1%) samples were positive for 'Ca. Liberibacter asiaticus'. When mixed infection was considered, 69 (48.9%) samples were positive for both 'Ca. P. asteri' and 'Ca. L. asiaticus'. Transmission electron microscopy (TEM) showed low titers of both walled and wall-less bodies in the phloem sieve tubes of HLB citrus. When transmission from symptomatic citrus to periwinkle (Catharanthus roseus) via dodder (Cuscuta campestris) was conducted, both phytoplasma and 'Ca. L. asiaticus' were detected from the affected periwinkle. In addition to yellowing/mottling, the infected periwinkle showed symptoms of virescence and phyllody which are commonly associated with phytoplasmal diseases. TEM analysis of affected periwinkle revealed pleomorphic and wall-less organisms, characteristic of phytoplasmas, filling some phloem sieve tubes. In contrast, walled bacteria were at low titer. This study showed that in addition to 'Ca. L. asiaticus', a phytoplasma related to 'Ca. P. asteri' could also be detected in citrus showing HLB symptoms in Guangdong.

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.

Association of phytoplasmas and viruses with malformed clovers.

Plants of Trifolium spp. exhibiting two different kinds of symptoms--phyllody associated with yellowing/reddening, and dwarf growth habit without floral abnormalities--were observed in several areas of the Czechia. Nested polymerase chain reaction (PCR) with phytoplasma specific primers, and restriction fragment length polymorphism (RFLP) analyses of 16SrDNA revealed that phyllody of T. repens was associated with phytoplasmas belonging to the 16SrI-C subgroup. Similar symptoms in T. hybridum and T. pratense plants revealed the presence of phytoplasmas belonging to two subgroups: 16SrI-C and 16SrIII-B. Dwarf disease of cultivated T. pratense plants was associated with more than one agent: 11 of 20 plants examined by PCR/RFLP analysis revealed the presence of phytoplasmas belonging to four distinct subgroups: 16SrI-B, 16SrI-C, 16SrIII-B and 16SrX-A. Moreover, two kinds of bacilliform virions were observed in ultrathin sections of 15 T. pratense plants. Particles occurred mostly in the parenchymatous cells of vascular bundles and were located in the cytoplasm as aggregates within an extended network of membranous cisternae. Phytoplasmas and rhabdoviruses occurred singly, and both together or in co-presence with filamentous virus-like particles.