Non-destructive insect metabarcoding for surveillance and biosecurity in citrus orchards: recording the good, the bad and the psyllids.

Background: The Australian citrus industry remains one of the few in the world to be unaffected by the African and the Asian citrus psyllids, Trioza erytreae Del Guercio and Diaphorina citri Kuwayama, respectively, and the diseases their vectored bacteria can cause. Surveillance, early detection, and strict quarantine measures are therefore fundamental to safeguard Australian citrus. However, long-term targeted surveillance for exotic citrus pests can be a time-consuming and expensive activity, often relying on manually screening large numbers of trap samples and morphological identification of specimens, which requires a high level of taxonomic knowledge. Methods: Here we evaluated the use of non-destructive insect metabarcoding for exotic pest surveillance in citrus orchards. We conducted an 11-week field trial, between the months of December and February, at a horticultural research farm (SuniTAFE Smart Farm) in the Northwest of Victoria, Australia, and processed more than 250 samples collected from three types of invertebrate traps across four sites. Results: The whole-community metabarcoding data enabled comparisons between different trapping methods, demonstrated the spatial variation of insect diversity across the same orchard, and highlighted how comprehensive assessment of insect biodiversity requires use of multiple complimentary trapping methods. In addition to revealing the diversity of native psyllid species in citrus orchards, the non-targeted metabarcoding approach identified a diversity of other pest and beneficial insects and arachnids within the trap bycatch, and recorded the presence of the triozid Casuarinicola cf warrigalensis for the first time in Victoria. Ultimately, this work highlights how a non-targeted surveillance approach for insect monitoring coupled with non-destructive DNA metabarcoding can provide accurate and high-throughput species identification for biosecurity and biodiversity monitoring.

First report of ryegrass cyst nematode, Heterodera mani, in Tasmania, Australia.

Cyst nematodes of the genus Heterodera are a major group of sedentary plant parasites causing a significant economic impact, restricting production and market access globally (Moens et al. 2018). The ryegrass cyst nematode Heterodera mani is in the Avenae group and is found predominantly in pastures and grasslands in Europe, California, and South Africa. It was first described by Mathews (1971) from Northern Ireland. Known hosts are grasses (family Poaceae), principally Lolium perenne (perennial ryegrass), but also Dactylis glomerata (cat grass) and Festuca pratensis (meadow fescue) (Subbotin et al. 2010). Mowat (1974) reported that H. mani causes negligible damage to the yield of L. perenne in pot trials; however, Maas & Brinkman (1982) determined that it may cause significant damage to spring and autumn-sown perennial ryegrass in field conditions. During a routine examination for potato cyst nematode from a farm near Mawbanna in north-west Tasmania, Australia, several pale to dark brown Heterodera cysts were extracted that were lemon shaped with the presence of a small vulval cone at the posterior end and a distinct neck. The J2 (n=20) stylet length ranged from 24-26 µm with round knobs deeply concave anteriorly, hyaline tail length was 37-42 µm, true tail length ranged from 59-68 µm and total body length varied from 526-559 µm. All the above characters match those described for H. mani (Subbotin et al. 2010). To verify this identification, DNA was extracted from five individual J2 juveniles from a single cyst using QIAamp DNA micro kit (Qiagen®), and two gene regions amplified: internal transcribed spacer region of ribosomal RNA (ITS-rRNA) with primer pair AB28 and TW81 and cytochrome oxidase 1 (CO1) with primer pair JB3 and JB5 (Bowles et al. 1992; Curran et al. 1994; Derycke et al. 2005). One PCR reaction contained 10 µM (1 µl each) of each primer, 12.5 µl of OneTaq® DNA Polymerase and 5 µl of DNA template with a final volume of 25 µl. PCR products were sent for purification and Sanger sequencing at Macrogen (Seoul, Rep. of Korea). All resulting sequences were trimmed, aligned, and analysed using Geneious Prime® 2022.0.1 (www.geneious.com). Five ITS sequences (accessions ON402852-ON402856) and five CO1 sequences (accessions ON402857-ON402861) were submitted to GenBank. These ITS sequences were very similar to each other and exhibited 99.16-100% similarity with that of H. mani isolate from Hamminkeln, Germany (AY148377) (Subbotin et al. 2018). The CO1 sequences exhibited 98.96-100% similarity with that of H. mani isolate from Washington, USA (MG523097) (Subbotin et al. 2003). Obtained sequences were mapped to reference sequences downloaded from NCBI GenBank and maximum likelihood phylogenetic trees were calculated. Due to the lack of further living nematode material, pot experiments were not performed. Such experiments are not feasible in Tasmania currently and transfer of live nematode material to the Australian mainland presents logistic and legal issues. However, morphological and molecular evidence for species determination of H. mani was unequivocal and contributes to the list of cyst nematode species present in Australia. This is the first detection of H. mani in Australia and is a range extension of the species from North America, Africa, and Europe to Australia. The nematode may cause damage to perennial ryegrass in Australia, however, impact on yield still needs to be investigated.

A diagnostic LAMP assay for rapid identification of an invasive plant pest, fall armyworm Spodoptera frugiperda (Lepidoptera: Noctuidae).

Fall armyworm (FAW), Spodoptera frugiperda (Lepidoptera: Noctuidae), is a highly polyphagous invasive plant pest that has expanded its global geographic distribution, including recently into much of Australia. Rapid diagnostic tests are required for identification of FAW to assist subsequent management and control. We developed a new loop-mediated isothermal amplification (LAMP) assay based on the mitochondrial cytochrome c oxidase subunit I (COI) gene for accurate and timely diagnosis of FAW in the field. The specificity of the new assay was tested against a broad panel of twenty non-target noctuids, including eight other Spodoptera species. Only S. frugiperda samples produced amplification within 20 min, with an anneal derivative temperature of 78.3 ± 0.3 °C. A gBlock dsDNA fragment was developed and trialled as a synthetic positive control, with a different anneal derivative of 81 °C. The new FAW LAMP assay was able to detect FAW DNA down to 2.4 pg, similar to an existing laboratory-based real-time PCR assay. We also trialled the new FAW assay with a colorimetric master mix and found it could successfully amplify positive FAW samples in half the time compared to an existing FAW colorimetric LAMP assay. Given the high sensitivity and rapid amplification time, we recommend the use of this newly developed FAW LAMP assay in a portable real-time fluorometer for in-field diagnosis of FAW.

The Incidence and Genetic Diversity of Apple Mosaic Virus (ApMV) and Prune Dwarf Virus (PDV) in Prunus Species in Australia.

Apple mosaic virus (ApMV) and prune dwarf virus (PDV) are amongst the most common viruses infecting Prunus species worldwide but their incidence and genetic diversity in Australia is not known. In a survey of 127 Prunus tree samples collected from five states in Australia, ApMV and PDV occurred in 4 (3%) and 13 (10%) of the trees respectively. High-throughput sequencing (HTS) of amplicons from partial conserved regions of RNA1, RNA2, and RNA3, encoding the methyltransferase (MT), RNA-dependent RNA polymerase (RdRp), and the coat protein (CP) genes respectively, of ApMV and PDV was used to determine the genetic diversity of the Australian isolates of each virus. Phylogenetic comparison of Australian ApMV and PDV amplicon HTS variants and full length genomes of both viruses with isolates occurring in other countries identified genetic strains of each virus occurring in Australia. A single Australian Prunus infecting ApMV genetic strain was identified as all ApMV isolates sequence variants formed a single phylogenetic group in each of RNA1, RNA2, and RNA3. Two Australian PDV genetic strains were identified based on the combination of observed phylogenetic groups in each of RNA1, RNA2, and RNA3 and one Prunus tree had both strains. The accuracy of amplicon sequence variants phylogenetic analysis based on segments of each virus RNA were confirmed by phylogenetic analysis of full length genome sequences of Australian ApMV and PDV isolates and all published ApMV and PDV genomes from other countries.

Analysis of intra-host genetic diversity of Prunus necrotic ringspot virus (PNRSV) using amplicon next generation sequencing.

PCR amplicon next generation sequencing (NGS) analysis offers a broadly applicable and targeted approach to detect populations of both high- or low-frequency virus variants in one or more plant samples. In this study, amplicon NGS was used to explore the diversity of the tripartite genome virus, Prunus necrotic ringspot virus (PNRSV) from 53 PNRSV-infected trees using amplicons from conserved gene regions of each of PNRSV RNA1, RNA2 and RNA3. Sequencing of the amplicons from 53 PNRSV-infected trees revealed differing levels of polymorphism across the three different components of the PNRSV genome with a total number of 5040, 2083 and 5486 sequence variants observed for RNA1, RNA2 and RNA3 respectively. The RNA2 had the lowest diversity of sequences compared to RNA1 and RNA3, reflecting the lack of flexibility tolerated by the replicase gene that is encoded by this RNA component. Distinct PNRSV phylo-groups, consisting of closely related clusters of sequence variants, were observed in each of PNRSV RNA1, RNA2 and RNA3. Most plant samples had a single phylo-group for each RNA component. Haplotype network analysis showed that smaller clusters of PNRSV sequence variants were genetically connected to the largest sequence variant cluster within a phylo-group of each RNA component. Some plant samples had sequence variants occurring in multiple PNRSV phylo-groups in at least one of each RNA and these phylo-groups formed distinct clades that represent PNRSV genetic strains. Variants within the same phylo-group of each Prunus plant sample had ≥97% similarity and phylo-groups within a Prunus plant sample and between samples had less ≤97% similarity. Based on the analysis of diversity, a definition of a PNRSV genetic strain was proposed. The proposed definition was applied to determine the number of PNRSV genetic strains in each of the plant samples and the complexity in defining genetic strains in multipartite genome viruses was explored.

Enhanced stabilization of the Tobacco mosaic virus using protic ionic liquids.

We report on the use of protic ionic liquids, pILs, as solvents for the solubilisation and stabilization of viruses. We show that the shelf life of the pIL stabilized tobacco mosaic virus is significantly enhanced when compared to traditional phosphate buffer. This has new opportunities for the preparation, characterization and storage of viruses and virus based technologies.