Design of a diagnostic system based on molecular markers derived from the ascomycetes pan-genome analysis: The case of Fusarium dieback disease

A sensitive visual method for onsite detection of quarantine pathogenic bacteria from horticultural crops using an LbCas12a variant system

Pre-planting testing of seeds and plantlets for the existence of quarantine pathogens is an important phytosanitary measure. The CRISPR-mediated molecular diagnostic methodologies are being developed for pathogens detection, but many challenges remain. Here, we profiled an engineered Crispr/LbCas12a variant (LbCas12a-5M) that has more robust trans-cleavage activity and a wider PAM sequences (TNTN) preference than wild type. We developed a procedure for screening specific sequences of bacterial plant pathogens, and the designed species-specific crRNA displayed no cross-reactions with other bacterial species. Combined with a simple extraction of bacterial DNA, an LbCas12a-5M-based visual detection technique was established and optimized for detecting quarantine pathogens Erwinia amylovora and Acidovorax citrulli with detection limits up to 40 CFU/reaction and a sensitivity consistent with qPCR assay. This protocol was faster and simpler than qPCR, requiring 40 min or less from sample preparation. We further validated the potential application of the method by showing that it can be used for rapid and accurate diagnosis of A. citrulli on seeds of watermelon, with 100% agreement with the results of qPCR assay. The developed method simplifies the detection of pathogens and provides cost-effective countermeasures to quarantine interventions.

Molecular evidence of the avocado defense response to Fusarium kuroshium infection: a deep transcriptome analysis using RNA-Seq

Fusarium kuroshium is a novel member of the Ambrosia Fusarium Clade (AFC) that has been recognized as one of the symbionts of the invasive Kuroshio shot hole borer, an Asian ambrosia beetle. This complex is considered the causal agent of Fusarium dieback, a disease that has severely threatened natural forests, landscape trees, and avocado orchards in the last 8 years. Despite the interest in this species, the molecular responses of both the host and F. kuroshium during the infection process and disease establishment remain unknown. In this work, we established an in vitro pathosystem using Hass avocado stems inoculated with F. kuroshium to investigate differential gene expression at 1, 4, 7 and 14 days post-inoculation. RNA-seq technology allowed us to obtain data from both the plant and the fungus, and the sequences obtained from both organisms were analyzed independently. The pathosystem established was able to mimic Fusarium dieback symptoms, such as carbohydrate exudation, necrosis, and vascular tissue discoloration. The results provide interesting evidence regarding the genes that may play roles in the avocado defense response to Fusarium dieback disease. The avocado data set comprised a coding sequence collection of 51,379 UniGenes, from which 2,403 (4.67%) were identified as differentially expressed. The global expression analysis showed that F. kuroshium responsive UniGenes can be clustered into six groups according to their expression profiles. The biologically relevant functional categories that were identified included photosynthesis as well as responses to stress, hormones, abscisic acid, and water deprivation. Additionally, processes such as oxidation-reduction, organization and biogenesis of the cell wall and polysaccharide metabolism were detected. Moreover, we identified orthologues of nucleotide-binding leucine-rich receptors, and their possible action mode was analyzed. In F. kuroshium, we identified 57 differentially expressed genes. Interestingly, the alcohol metabolic process biological category had the highest number of upregulated genes, and the enzyme group in this category may play an important role in the mechanisms of secondary metabolite detoxification. Hydrolytic enzymes, such as endoglucanases and a pectate lyase, were also identified, as well as some proteases. In conclusion, our research was conducted mainly to explain how the vascular tissue of a recognized host of the ambrosia complex responds during F. kuroshium infection since Fusarium dieback is an ambrosia beetle-vectored disease and many variables facilitate its establishment.