Abstract
Rose black spot is one of the most severe diseases of field-grown roses. Though R-genes have been characterised, little information is known about the molecular details of the interaction between pathogen and host. Based on the recently published genome sequence of the black spot fungus, we analysed gene models with various bioinformatic tools utilising the expression data of infected host tissues, which led to the prediction of 827 secreted proteins. A significant proportion of the predicted secretome comprises enzymes for the degradation of cell wall components, several of which were highly expressed during the first infection stages. As the secretome comprises major factors determining the ability of the fungus to colonise its host, we focused our further analyses on predicted effector candidates. In total, 52 sequences of 251 effector candidates matched several bioinformatic criteria of effectors, contained a Y/F/WxC motif, and did not match annotated proteins from other fungi. Additional sequences were identified based on their high expression levels during the penetration/haustorium formation phase and/or by matching known effectors from other fungi. Several host genotypes that are resistant to the sequenced isolate but differ in the R-genes responsible for this resistance are available. The combination of these genotypes with functional studies of the identified candidate effectors will allow the mechanisms of the rose black spot interaction to be dissected.
Highlights
Black spot disease is one of the most severe and damaging diseases of field-grown roses
The 14,004 predicted genes of the draft genome sequence of the D. rosae isolate DortE4 was the basis for the prediction of the secretome
Because TargetP uses the same algorithm for the prediction of signal peptide (SP) as SignalP and WolfPSort has a low sensitivity (Sperschneider et al, 2015b), these data are only reported as additional information and not as disqualifiers
Summary
Black spot disease is one of the most severe and damaging diseases of field-grown roses It is caused by the hemibiotrophic ascomycete Diplocarpon rosae (whose anamorph is Marssonina rosae). After the germination of bicellular conidia, the fungus penetrates the cuticle via an appressorium within the first 12 h post-inoculation (hpi) and develops intercellular haustoria to extract nutrients from the plant This process takes two to three days and marks the early biotrophic stage of the pathogen, which is followed by a mixed biotrophic/ necrotrophic stage that leads to some tissue damage and results (after five to seven days) in the development of acervuli, where new conidia are formed (Aronescu, 1934; Frick, 1943; Gachomo and Kotchoni, 2007)
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