Transcriptome analysis of the fungal pathogen Rosellinia necatrix during infection of a susceptible avocado rootstock identifies potential mechanisms of pathogenesis.

BACKGROUND: White root rot disease caused by Rosellinia necatrix is one of the most important threats affecting avocado productivity in tropical and subtropical climates. Control of this disease is complex and nowadays, lies in the use of physical and chemical methods, although none have proven to be fully effective. Detailed understanding of the molecular mechanisms underlying white root rot disease has the potential of aiding future developments in disease resistance and management. In this regard, this study used RNA-Seq technology to compare the transcriptomic profiles of R. necatrix during infection of susceptible avocado 'Dusa' roots with that obtained from the fungus cultured in rich medium. RESULTS: The transcriptomes from three biological replicates of R. necatrix colonizing avocado roots (RGA) and R. necatrix growing on potato dextrose agar media (RGPDA) were analyzed using Illumina sequencing. A total of 12,104 transcripts were obtained, among which 1937 were differentially expressed genes (DEG), 137 exclusively expressed in RGA and 160 in RGPDA. During the root infection process, genes involved in the production of fungal toxins, detoxification and transport of toxic compounds, hormone biosynthesis, gene silencing and plant cell wall degradation were overexpressed. Interestingly, 24 out of the 137 contigs expressed only during R. necatrix growth on avocado roots, were predicted as candidate effector proteins (CEP) with a probability above 60%. The PHI (Pathogen Host Interaction) database revealed that three of the R. necatrix CEP showed homology with previously annotated effectors, already proven experimentally via pathogen-host interaction. CONCLUSIONS: The analysis of the full-length transcriptome of R. necatrix during the infection process is suggesting that the success of this fungus to infect roots of diverse crops might be attributed to the production of different compounds which, singly or in combination, interfere with defense or signaling mechanisms shared among distinct plant families. The transcriptome analysis of R. necatrix during the infection process provides useful information and facilitates further research to a more in -depth understanding of the biology and virulence of this emergent pathogen. In turn, this will make possible to evolve novel strategies for white root rot management in avocado.

The CaMV 35S promoter is highly active on floral organs and pollen of transgenic strawberry plants.

We have evaluated the expression of the reporter beta-glucuronidase (GUS) gene driven by the cauliflower mosaic virus 35S (CaMV 35S) promoter in flowers and pollen from 14 independent transgenic strawberry lines. Of the 14 lines evaluated, 13 (92.8%) showed GUS activity--as estimated by the histochemical GUS assay--in some floral organs, with expression being most common in the flower stem, sepals, petals, ovary and stigma. Ten of these thirteen transgenic lines (77%) showed GUS activity in pollen, although the percentages of positive pollen per flower varied greatly among the different lines. A study of the GUS expression during pollen maturation showed that the (CaMV 35S) promoter showed low expression in pollen from flower buds before anthesis but was activated in mature pollen following anther dehiscence. The percentages of pollen grains that showed GUS activity ranged from 2.1% to 46.3%. These percentages were similar or even higher when mature pollen was stored dry at room temperature for 2 weeks. After 5 weeks of storage, the percentages of GUS-positive pollen decreased in two of the six lines analysed but remained at similar values in the other four lines. GUS activity was also measured in protein extracts of mature pollen by means of the fluorometric GUS assay, with the values obtained ranging from 3.8 micromol MU mg protein(-1) h(-1) to 0.26 micromol MU mg protein(-1) h(-1). Contrary to the generally held view that the CaMV 35S promoter is virtually silent in pollen, we conclude that it is highly expressed in transgenic strawberry pollen.

Shoot regeneration and Agrobacterium-mediated transformation of Fragaria vesca L.

An efficient and reliable method for shoot regeneration from leaf disks of Fragaria vesca L. has been developed. This protocol has been successfully employed to obtain transformed plants using Agrobacterium tumefaciens as gene vector. Murashige and Skoog basal medium supplemented with benzyladenine (4 mg/l) and indole-3-butyric acid (0.25 mg/l) induced the maximum percentage of shoot regeneration (98%) and the highest number of shoot colonies per explant (4.6) after 8 weeks of culture. Isolated shoots would elongate and proliferate when the benzyladenine concentration was lowered to 0.5 mg/l. The established protocol for shoot regeneration was employed to transform leaf disks using Agrobacterium tumefaciens carrying the plasmid pBI121. A 7.7% of the inoculated explants showed kanamycin resistance after 10 weeks of selection in a medium containing 25 mg/l of this antibiotic. The transgenic shoots obtained were rooted in the presence of 25 mg/ kanamycin and successfully acclimatized. The final percentage of transformation obtained based on beta-glucuronidase expression was 6.9%.