Abstract
Rosellinia necatrix is the causal agent of avocado white root rot (WRR). Control of this soil-borne disease is difficult, and the use of tolerant rootstocks may present an effective method to lessen its impact. To date, no studies on the molecular mechanisms regulating the avocado plant response towards this pathogen have been undertaken. To shed light on the mechanisms underpinning disease susceptibility and tolerance, molecular analysis of the gene’s response in two avocado rootstocks with a contrasting disease reaction was assessed. Gene expression profiles against R. necatrix were carried out in the susceptible ‘Dusa’ and the tolerant selection BG83 avocado genotypes by micro-array analysis. In ‘Dusa’, the early response was mainly related to redox processes and cell-wall degradation activities, all becoming enhanced after disease progression affected photosynthetic capacity, whereas tolerance to R. necatrix in BG83 relied on the induction of protease inhibitors and their negative regulators, as well as genes related to tolerance to salt and osmotic stress such as aspartic peptidase domain-containing proteins and gdsl esterase lipase proteins. In addition, three protease inhibitors were identified, glu protease, trypsin and endopeptidase inhibitors, which were highly overexpressed in the tolerant genotype when compared to susceptible ‘Dusa’, after infection with R. necatrix, reaching fold change values of 52, 19 and 38, respectively. The contrasting results between ‘Dusa’ and BG83 provide new insights into the different mechanisms involved in avocado tolerance to Phytophthora cinnamomi and R. necatrix, which are consistent with their biotrophic and necrotrophic lifestyles, respectively. The differential induction of genes involved in salt and osmotic stress in BG83 could indicate that R. necatrix penetration into the roots is associated with osmotic effects, suggesting that BG83’s tolerance to R. necatrix is related to the ability to withstand osmotic imbalance. In addition, the high expression of protease inhibitors in tolerant BG83 compared to susceptible ‘Dusa’ after infection with the pathogen suggests the important role that these proteins may play in the defence of avocado rootstocks against R. necatrix.
Highlights
Avocado (Persea americana Mill.), a member of the Lauraceae, is an important fruit crop in over 50 countries
This BG83 tolerant response to R. necatrix is different from the ‘Dusa’ tolerant response to P. cinnamomi, in which tolerance was associated with a greater ability to restore both assimilation rates (AN) and gs at similar levels as those seen in the non-inoculated control [16]
The early response was mainly related to oxido-reduction processes and cell-wall degradation activities, which became more noticeable after the photosynthetic capacity was affected by disease progression
Summary
Avocado (Persea americana Mill.), a member of the Lauraceae, is an important fruit crop in over 50 countries. There has been an increase in consumption worldwide during the last decade, bringing a certain concern about the difficulties of satisfying the demand in the near future. In this regard, efforts to increase avocado production by decreasing the incidence of avocado diseases are important. Significant losses in avocado production result from root rots caused by soilborne pathogens such as Phytophthora cinnamomi (Phytophthora root rot; PRR) and Rosellinia necatrix (white root rot; WRR). While P. cinnamomi affects avocado plantations worldwide, infections caused by R. necatrix have a considerable impact on avocado orchards in temperate regions, Europe and Asia; recent out-breaks of this pathogen in other areas, such as California, Mexico, Korea and South Africa, have increased the interest in gaining basic knowledge of its interaction with avocado
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