‘Phytophthora cinnamomi’ Rands (Pc), is one of the phytopathogen with the highest impact causing crown rot, trunk canker, and root rot on forest and non-forest species including chesnut, ‘Quercus’, avocado, or tomato. The life cycle of Pc involves the production of asexual motile high virulence zoospores (Zs), allowing the dispersion of them through soil and water currents by the aquatic environment, establishing a high biodiversity on below-ground interactions with several hosts. Despite the high biodiversity on virulence and impact of this phytopathogen, the knowledge we have about the management and physiology of Zs under strictly controlled conditions, to study and follow the infection process on plants remains still scarce. In this poster, we show how we mimic nature in the laboratory, inoculating plants with Zs and studying the survival of Zs and the infection process in the non-forest system host tomato. This pathosystem allowed us to compare and study the biodiversity on the modes of infection of Pc with forest host. The physiology of Zs and the plant response to Pc were studied by different techniques including fluorescence, QRT-PCR, and RNA sequencing, allowing us to extend the current knowledge we have about the biodiversity and capacities of Pc to interact in belowground environment with forest and non-forest plant species.
’Phytophthora cinnamomi’ Rands (Pc), is one of the phytopathogen with the highest impact causing crown rot, trunk canker, and root rot on forest and non-forest species including chesnut, ‘Quercus’, avocado, or tomato. The life cycle of Pc involves the production of asexual motile high virulence zoospores (Zs), allowing the dispersion of them through soil and water currents by the aquatic environment, establishing a high biodiversity on below-ground interactions with several hosts. Despite the high biodiversity on virulence and impact of this phytopathogen, the knowledge we have about the management and physiology of Zs under strictly controlled conditions, to study and follow the infection process on plants remains still scarce. In this poster, we show how we mimic nature in the laboratory, inoculating plants with Zs and studying the survival of Zs and the infection process in the non-forest system host tomato. This pathosystem allowed us to compare and study the biodiversity on the modes of infection of Pc with forest host. The physiology of Zs and the plant response to Pc were studied by different techniques including fluorescence, QRT-PCR, and RNA sequencing, allowing us to extend the current knowledge we have about the biodiversity and capacities of Pc to interact in belowground environment with forest and non-forest plant species. Read More
Related posts:
The tomato-‘Phytophtora cinnamomi’ pathosystem
How Do Pathogens Evolve Novel Virulence Activities?
An improved method to study Phytophthora cinnamomi Rands zoospores interactions with host
The Pseudomonas syringae pv. tomato DC3000 PSPTO_0820 multidrug transporter is involved in resistance to plant antimicrobials and bacterial survival during tomato plant infection
Editorial: Beneficial effects of fungal endophytes in major agricultural crops
Botanical Collection Patterns and Conservation Categories of
the Most Traded Timber Species from the Ecuadorian Amazon:
The Role of Protected Areas