Genome drafts of four phytoplasma strains of the ribosomal group 16SrIII.

By applying a coverage-based read selection and filtration through a healthy plant dataset, and a post-assembly contig selection based on homology and linkage, genome sequence drafts were obtained for four phytoplasma strains belonging to the 16SrIII group (X disease clade), namely Vaccinium Witches' Broom phytoplasma (647 754 nt in 272 contigs), Italian Clover Phyllody phytoplasma strain MA (597 245 nt in 197 contigs), Poinsettia branch-inducing phytoplasma strain JR1 (631 440 nt in 185 contigs) and Milkweed Yellows phytoplasma (583 806 nt in 158 contigs). Despite assignment to different 16SrIII subgroups, the genomes of the four strains were similar, comprising a highly conserved core (92-98 % similar in their nucleotide sequence among each other over alignments about 500 kb in length) and a minor strain-specific component. As far as their protein complement was concerned, they did not differ significantly in their basic metabolism potential from the genomes of other wide-host-range phytoplasmas sequenced previously, but were distinct from strains of other species, as well as among each other, in genes encoding functions conceivably related to interactions with the host, such as membrane trafficking components, proteases, DNA methylases, effectors and several hypothetical proteins of unknown function, some of which are likely secreted through the Sec-dependent secretion system. The four genomes displayed a group of genes encoding hypothetical proteins with high similarity to a central domain of IcmE/DotG, a core component of the type IVB secretion system of Gram-negative Legionella spp. Conversely, genes encoding functional GroES/GroEL chaperones were not detected in any of the four drafts. The results also indicated the significant role of horizontal gene transfer among different 'Candidatus Phytoplasma' species in shaping phytoplasma genomes and promoting their diversity.

The influence of local factors on the prediction of fumonisin contamination in maize.

BACKGROUND: Contamination by mycotoxins is a major concern to the maize industry in north-east Italy where maize grain is often spoiled by Fusarium spp. In this work, fumonisins, deoxynivalenol and zearalenone were determined and an artificial neural network (ANN) model suitable for predicting mycotoxin contamination of maize at harvest time was developed. RESULTS: The occurrence of deoxynivalenol and zearalenone was very limited, while fumonisins concentration ranged from 163 and to 3663 µg kg(-1) in 2007, and from 333 to 11473 µg kg(-1) in 2008. Statistical data analysis of factors affecting fumonisins concentration revealed that irrigation, chemical treatment against the European corn borer and harvest date significantly affected the level of contamination (P < 0.05), although the relevance of the factors was different in 2007 and 2008. The neural network approach showed a significant correlation between ascertained values and predictions based on agronomic data. CONCLUSION: This is the first time that an artificial neural network has been used to predict fumonisin accumulation in maize: the prediction has been shown to have the potential for the development of a new approach for the rapid cataloging of grain lots.

On the alleged origin of geminiviruses from extrachromosomal DNAs of phytoplasmas.

BACKGROUND: Several phytoplasmas, wall-less phloem limited plant pathogenic bacteria, have been shown to contain extrachromosomal DNA (EcDNA) molecules encoding a replication associated protein (Rep) similar to that of geminiviruses, a major group of single stranded (ss) DNA plant viruses. On the basis of that observation and of structural similarities between the capsid proteins of geminiviruses and the Satellite tobacco necrosis virus, it has been recently proposed that geminiviruses evolved from phytoplasmal EcDNAs by acquiring a capsid protein coding gene from a co-invading plant RNA virus. RESULTS: Here we show that this hypothesis has to be rejected because (i) the EcDNA encoded Rep is not of phytoplasmal origin but has been acquired by phytoplasmas through horizontal transfer from a geminivirus or its ancestor; and (ii) the evolution of geminivirus capsid protein in land plants implies missing links, while the analysis of metagenomic data suggests an alternative scenario implying a more ancient evolution in marine environments. CONCLUSION: The hypothesis of geminiviruses evolving in plants from DNA molecules of phytoplasma origin contrasts with other findings. An alternative scenario concerning the origin and spread of Rep coding phytoplasmal EcDNA is presented and its implications on the epidemiology of phytoplasmas are discussed.