The redlegged earth mite draft genome provides new insights into pesticide resistance evolution and demography in its invasive Australian range

Umina

Hoffmann

2022

Preprint

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Pesticide resistance provides an intriguing system to study adaptative evolution because the candidate genes, the targets of pesticidal compounds, are often known a priori. In the redlegged earth mite, Halotydeus destructor (Trombidiformes: Penthaleidae, Tucker 1925), amplification of the acetylcholinesterase gene (ace), has led to the evolution of a gene complex. This gene complex has likely evolved in response to decades of organophosphate selection to control this invasive mite pest in the Australian grain and pasture industry. Using a pool-seq approach and experimental selection of H. destructor mites, we find that this ace gene complex likely contributes to organophosphate insensitivity in several ways. Firstly, we found that an increased copy number of individual ace genes within this complex is associated with organophosphate insensitivity. This effect may be general (increased copy number across all ace genes) or related to specific ace genes (the ancestral ace gene, HDE_14279, in a subset of populations). Secondly, target-site mutations (G119S, A201S, and F331Y) in the ancestral ace gene appear to be associated with evolved resistance to high doses of organophosphates. Thirdly, despite the low within-gene polymorphism, there were high levels among-gene polymorphisms at codons typically associated with resistance in other arthropods. These included fixed amino acids known to confer resistance (e.g., at codons 119, 201, 227, 331, and 441), but the functional effect of these mutations at amplified ace genes is yet to be characterised. Although we tested for the effects of other (non-ace) genes (e.g., detoxification on cuticular genes), our genome scans were equivocal and could not identify any other clear candidate genes contributing to organophosphate insensitivity. Our study makes headway on unravelling the intricacies of the ace gene complex in H. destructor and its phenotypic effects. We highlight the role of gene amplifications in adaptive evolution and its potential to generate polygenic-like mechanisms and non-convergent responses to selection among populations.

Section: Introductionmentioning

confidence: 83%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Aceandace-like genes of invasive redlegged earth mite: Copy number variation, target-site mutations, and their associations with organophosphate insensitivity

Umina

Hoffmann

2022

Preprint

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From laboratory to field: laboratory-measured pesticide resistance reflects outcomes of field-based control in the redlegged earth mite, Halotydeus destructor

Umina

McGrane²,

et al. 2023

Exp Appl Acarol

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Resistance to pesticides is typically identified via laboratory bioassays after field control failures are observed, but the results of such assays are rarely validated through experiments under field conditions. Such validation is particularly important when only a low-to-moderate level of resistance is detected in the laboratory. Here we undertake such a validation for organophosphate resistance in the agricultural pest mite Halotydeus destructor, in which low-to-moderate levels of resistance to organophosphorus pesticides have evolved in Australia. Using data from laboratory bioassays, we show that resistance to the organophosphate chlorpyrifos is higher (around 100-fold) than resistance to another organophosphate, omethoate (around 7-fold). In field trials, both these chemicals were found to effectively control pesticide-susceptible populations of H. destructor. However, when applied to a resistant mite population in the field, the effectiveness of chlorpyrifos was substantially decreased. In contrast, omethoate remained effective when tested alone or as a mixture with chlorpyrifos. We also show that two novel (non-pesticide) treatments, molasses and wood vinegar, are ineffective in controlling H. destructor when sprayed to pasture fields at rates of 4 L/ha. These findings suggest a close link between levels of resistance quantified through laboratory bioassays and the field effectiveness of pesticides; however, in the case of H. destructor, this does not necessarily mean all field populations possessing organophosphate resistance will respond similarly given the potentially complex nature of the underlying resistance mechanism(s).

The redlegged earth mite draft genome provides new insights into pesticide resistance evolution and demography in its invasive Australian range

Korhonen

Young

et al. 2022

Preprint

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We present the first draft genome for an invasive mite, the redlegged earth mite, Halotydeus destructor (Tucker, 1925), a major pest of Australian grains and pasture. Our de novo assembly comprised 132 contigs, with a total length of 48.90 Mb, an N50 of 874,492, an L50 of 14, a GC content of 45.3%, 14,583 putative genes, and a high level of completeness as assessed through benchmark single copy orthologs (BUSCO >89%). We use our draft genome to gain insights into the unresolved genetic mechanism of organophosphate resistance and demographic processes in the invasive Australian populations. We found that the acetylcholinesterase gene (ace), the target of organophosphate pesticides, has undergone a large amplification event in H. destructor. Copy number of this gene is considerably larger compared to most other arthropod pests and is likely to contribute to organophosphate resistance in this species. Congruent with a stepping-stone invasion pathway, we found that western populations were more genetically diverse (higher genomic heterozygosity) and had larger population sizes (as inferred from demographic analyses) relative to eastern populations. Our demographic analyses were, however, equivocal on the role of gene flow in shaping these genetic patterns. Due to the short evolutionary timescale since the H. destructor Australian invasion, it is challenging to discern between recent divergence with isolation versus ongoing gene flow. Our draft genome for H. destructor is the first assembled for mites in the family Penthaleidae of the order Trombidiformes, an under-represented group with few available reference genomes.