Chromosome-level assembly of the Phytophthora agathidicida genome reveals adaptation in effector gene families

Improved isolation and PCR detection of Phytophthora agathidicida oospores from soils

Phytophthora species are eukaryotic microorganisms responsible for severe dieback and root rot in plants worldwide, impacting crops, forests, and other important ecosystems. In New Zealand, P. agathidicida leads to fatal dieback in kauri (Agathis australis), long-lived endemic trees of significant cultural and ecological importance. A critical aspect of the P. agathidicida lifecycle is the production of oospores-thick-walled spores essential for long-term survival in soil, dispersal, and disease inoculation. However, their heterogeneous distribution in soils, robust structure, and dormant state make them challenging to detect using soil baiting or DNA-based methods. Soil baiting is the basis of most current testing for P. agathidicida, but baiting-based methods have low sensitivity, are slow, and require specialised facilities. To address these challenges, we developed and validated a PCR-based method for detecting P. agathidicida oospores directly from soil. Our approach includes a technique for separating oospores from soil, improved oospore lysis and DNA extraction, and a primer pair that targets a repeat region of the P. agathidicida genome with high sensitivity and specificity. The primers amplified the target product in all tested P. agathidicida isolates without cross-reactivity against eight non-target Phytophthora species. The detection limit was 1 femtogram of P. agathidicida DNA via endpoint PCR. Performance assessment against 65 soil samples from kauri forests revealed P. agathidicida in 69% of samples compared to only 11% detected by existing methods. By eliminating the need for baiting, our assay enhances the speed, accuracy, and accessibility of testing, thereby facilitating more comprehensive monitoring and improved disease management.

IMPORTANCE

Phytophthora species are notorious plant pathogens responsible for severe dieback and root rot diseases, significantly impacting crops, forests, and irreplaceable natural ecosystems. Rapid and accurate detection of these pathogens is essential for effective disease management. In New Zealand, P. agathidicida threatens the country's endemic kauri forests. In this study, we developed and validated a PCR-based method for detecting P. agathidicida oospores in soil. Oospores are long-lived, thick-walled spores that serve as key propagules for survival in soil and the spread of disease. Their robust structure and dormant state make them particularly challenging to detect using traditional soil baiting techniques or DNA-based methods. Our method is fast, accurate, and requires minimal equipment, enabling local testing and thereby empowering communities and enhancing surveillance efforts. Although developed for P. agathidicida, this method could be adapted for other plant pathogens, potentially improving disease management across various agricultural and ecological contexts.

Transient expression of fluorescent proteins and Cas nucleases in Phytophthora agathidicida via PEG-mediated protoplast transformation

Phytophthora species are eukaryotic plant pathogens that cause root rot and dieback diseases in thousands of plant species worldwide. Despite their significant economic and ecological impacts, fundamental molecular tools such as DNA transformation methods are not yet established for many Phytophthora species. In this study, we have established a PEG/calcium chloride (CaCl2)-mediated protoplast transformation method for Phytophthora agathidicida, the causal agent of kauri dieback disease. Adapting a protocol from Phytophthora sojae, we systematically optimized the protoplast digesting enzymes, recovery media composition and pH. Our findings reveal that chitinases are essential for P. agathidicida protoplast formation, and the optimum pH of the recovery medium is 5. The media type did not significantly impact protoplast regeneration. Using this protocol, we generated transformants using three plasmids (i.e. pTdTomatoN, pYF2-PsNLS-Cas9-GFP and pYF2-PsNLS-Cas12a-GFP), which expressed fluorescent proteins and/or Cas nucleases. The transformants were unstable unless maintained under antibiotic selective pressure; however, under selection, fluorescence was maintained across multiple generations and life cycle stages, including the production of fluorescent zoospores from transformed mycelia. Notably, we observed the expression of GFP-tagged Cas nucleases, which is promising for future CRISPR-Cas genome editing applications. This study demonstrates that P. agathidicida is amenable to PEG/CaCl2-mediated protoplast transformation. Although the resulting transformants require antibiotic selective pressure to remain stable, this transient expression system can be valuable for applications such as cell tracking, chemotaxis studies and CRISPR-Cas genome editing. The protocol also provides a foundation for further optimization of transformation methods. It serves as a valuable tool for exploring the molecular biology of P. agathidicida and potentially other closely related Phytophthora species.

A Method for the Separation of Phytophthora Oosporesfrom Soil for DNA-Based Detection

Here, we present a protocol for the isolation and detection of Phytophthora oospores directly from soil samples. Our method incorporates a novel technique for isolating Phytophthora oospores using filter pouches and an improved DNA extraction procedure specifically designed for oospores. While we have primarily developed this protocol for detecting P. agathidicida oospores using end-point PCR, we believe these methods can be readily adapted for other Phytophthora species. Furthermore, the DNA extracted using this protocol is suitable as input for other DNA-based detection methods.

Improved genome assembly of Candida auris strain B8441 and annotation of B11205

Candida auris is a fungal pathogen of significant worldwide concern, typically resistant to one or more antifungal drugs. We report a completed genome for clade Ia isolate B8441 and gene annotations of clade Ic isolate B11205. These resources will support public health investigations and population genomic studies of this pathogen.

Genomic and transcriptomic analyses of Phytophthora cinnamomi reveal complex genome architecture, expansion of pathogenicity factors, and host-dependent gene expression profiles

Phytophthora cinnamomi is a hemibiotrophic oomycete causing Phytophthora root rot in over 5,000 plant species, threatening natural ecosystems, forestry, and agriculture. Genomic studies of P. cinnamomi are limited compared to other Phytophthora spp. despite the importance of this destructive and highly invasive pathogen. The genome of two genetically and phenotypically distinct P. cinnamomi isolates collected from avocado orchards in California were sequenced using PacBio and Illumina sequencing. Genome sizes were estimated by flow cytometry and assembled de novo to 140-141 Mb genomes with 21,111-21,402 gene models. Genome analyses revealed that both isolates exhibited complex heterozygous genomes fitting the two-speed genome model. The more virulent isolate encodes a larger secretome and more RXLR effectors when compared to the less virulent isolate. Transcriptome analysis after P. cinnamomi infection in Arabidopsis thaliana, Nicotiana benthamiana, and Persea americana de Mill (avocado) showed that this pathogen deploys common gene repertoires in all hosts and host-specific subsets, especially among effectors. Overall, our results suggested that clonal P. cinnamomi isolates employ similar strategies as other Phytophthora spp. to increase phenotypic diversity (e.g., polyploidization, gene duplications, and a bipartite genome architecture) to cope with environmental changes. Our study also provides insights into common and host-specific P. cinnamomi infection strategies and may serve as a method for narrowing and selecting key candidate effectors for functional studies to determine their contributions to plant resistance or susceptibility.

RxLR Effectors: Master Modulators, Modifiers and Manipulators

Cytoplasmic effectors with an Arg-any amino acid-Arg-Leu (RxLR) motif are encoded by hundreds of genes within the genomes of oomycete Phytophthora spp. and downy mildew pathogens. There has been a dramatic increase in our understanding of the evolution, function, and recognition of these effectors. Host proteins with a wide range of subcellular localizations and functions are targeted by RxLR effectors. Many processes are manipulated, including transcription, post-translational modifications, such as phosphorylation and ubiquitination, secretion, and intracellular trafficking. This involves an array of RxLR effector modes-of-action, including stabilization or destabilization of protein targets, altering or disrupting protein complexes, inhibition or utility of target enzyme activities, and changing the location of protein targets. Interestingly, approximately 50% of identified host proteins targeted by RxLR effectors are negative regulators of immunity. Avirulence RxLR effectors may be directly or indirectly detected by nucleotide-binding leucine-rich repeat resistance (NLR) proteins. Direct recognition by a single NLR of RxLR effector orthologues conserved across multiple Phytophthora pathogens may provide wide protection of diverse crops. Failure of RxLR effectors to interact with or appropriately manipulate target proteins in nonhost plants has been shown to restrict host range. This knowledge can potentially be exploited to alter host targets to prevent effector interaction, providing a barrier to host infection. Finally, recent evidence suggests that RxLR effectors, like cytoplasmic effectors from fungal pathogen Magnaporthe oryzae, may enter host cells via clathrin-mediated endocytosis. [Formula: see text] Copyright © 2023 The Author(s). This is an open access article distributed under the CC BY-NC-ND 4.0 International license.

Harnessing CRISPR-Cas for oomycete genome editing

Oomycetes are a group of microorganisms that include pathogens responsible for devastating diseases in plants and animals worldwide. Despite their importance, the development of genome editing techniques for oomycetes has progressed more slowly than for model microorganisms. Here, we review recent breakthroughs in clustered regularly interspaced short palindromic repeats (CRISPR)-Cas technologies that are expanding the genome editing toolbox for oomycetes - from the original Cas9 study to Cas12a editing, ribonucleoprotein (RNP) delivery, and complementation. We also discuss some of the challenges to applying CRISPR-Cas in oomycetes and potential ways to overcome them. Advances in CRISPR-Cas technologies are being used to illuminate the biology of oomycetes, which ultimately can guide the development of tools for managing oomycete diseases.