scholarly journals The genome sequence of the avian vampire fly (Philornis downsi), an invasive nest parasite of Darwin’s finches in Galápagos

2021 ◽  
Author(s):  
Melia Romine ◽  
Sarah A Knutie ◽  
Carly M Crow ◽  
Grace J Vaziri ◽  
Jaime Chaves ◽  
...  
Keyword(s):  
Immune Responses ◽  
Insecticide Resistance ◽  
Genome Assembly ◽  
Gene Families ◽  
Mitigation Strategies ◽  
Future Research ◽  
Avian Host ◽  
Darwin's Finches ◽  
Philornis Downsi ◽  
Darwin’S Finches

Abstract The invasive avian vampire fly (Philornis downsi, Diptera: Muscidae) is considered one of the greatest threats to the endemic avifauna of the Galápagos Islands. The fly larvae parasitize nearly every passerine species, including Darwin’s finches. Most P. downsi research to date has focused on the effects of the fly on avian host fitness and mitigation methods. A lag in research related to the genetics of this invasion demonstrates, in part, the need to develop full-scale genomic resources with which to address further questions within this system. In this study, an adult female P. downsi was sequenced to generate a high-quality genome assembly. We examined various features of the genome (e.g., coding regions, non-coding transposable elements) and carried out comparative genomics analysis against other dipteran genomes. We identified lists of gene families that are significantly expanding or contracting in P. downsi that are related to insecticide resistance, detoxification, and counter defense against host immune responses. The P. downsi genome assembly provides an important resource for studying the molecular basis of successful invasion in the Galápagos and the dynamics of its population across multiple islands. The findings of significantly changing gene families associated with insecticide resistance and immune responses highlight the need for further investigations into the role of different gene families in aiding the fly’s successful invasion. Furthermore, this genomic resource provides a necessary tool to better inform future research studies and mitigation strategies aimed at minimizing the fly’s impact on Galápagos birds.

scholarly journals The genome sequence of the avian vampire fly (Philornis downsi), an invasive nest parasite of Darwins finches in Galpagos

2021 ◽  
Author(s):  
Melia Romine ◽  
Sarah A Knutie ◽  
Carly M Crow ◽  
Grace J Vaziri ◽  
Jaime Chaves ◽  
...  
Keyword(s):  
Immune Responses ◽  
Insecticide Resistance ◽  
Genome Assembly ◽  
Gene Families ◽  
Mitigation Strategies ◽  
Future Research ◽  
Host Immune Responses ◽  
Philornis Downsi ◽  
Genomic Resource ◽  
Mitigation Methods

The invasive avian vampire fly (Philornis downsi) is considered one of the greatest threats to the unique and endemic avifauna of the Galpagos Islands, Ecuador. The fly parasitizes nearly every passerine species, including Darwins finches, in the Galpagos. The fly is thought to have been introduced from mainland Ecuador, although the full pathway of invasion is not yet known. The majority of research to date has focused on the effects of the fly on the fitness of avian hosts and explorations of mitigation methods. A lag in research related to the genetics of this invasion demonstrates, in part, a need to develop full-scale genomic resources with which to address further questions within this system. In this study, an adult P. downsi collected from San Cristobal Island within the Galpagos archipelago was sequenced to generate a high-quality genome assembly. We examined various features of the genome (e.g., coding regions, non-coding transposable elements) and carried out comparative genomics analysis against other dipteran genomes. We identified lists of gene families that are significantly expanding/contracting in P. downsi >that are related to insecticide resistance, detoxification, and potential feeding ecology and counter defense against host immune responses. The P. downsi genome assembly provides an important foundational resource for studying the molecular basis of its successful invasion in the Galpagos and the dynamics of its population across multiple islands. The findings of significantly changing gene families associated with insecticide resistance and immune responses highlight the need for further investigations into the role of different gene families in aiding the flys successful invasion. Furthermore, this genomic resource will also better help inform future research studies and mitigation strategies aimed at minimizing the flys impact on the birds of the Galpagos.

scholarly journals A Scaffold-Level Genome Assembly of the Pirate Bug, Orius Laevigatus, and a Comparative Analysis of Insecticide Resistance-Related Gene Families with Hemipteran Crop Pests

2021 ◽  
Author(s):  
Emma Bailey ◽  
Linda Field ◽  
Christopher Rawlings ◽  
Rob King ◽  
Fady Mohareb ◽  
...  
Keyword(s):  
Insecticide Resistance ◽  
Genome Assembly ◽  
Hybrid Approach ◽  
Gene Families ◽  
Resistance Mechanisms ◽  
Target Site ◽  
Genomic Information ◽  
Orius Laevigatus ◽  
Crop Pests ◽  
Comparative Analyses

Abstract Background: The pirate bug, Orius laevigatus, is a highly effective beneficial predator of crop pests including aphids, spider mites and thrips in integrated pest management (IPM) programmes. No genomic information is currently available for O. laevigatus, as is the case for the majority of beneficial predators which feed on crop pests. In contrast, genomic information for crop pests is far more readily available. The lack of publicly available genomes for beneficial predators to date has limited our ability to perform comparative analyses of genes encoding potential insecticide resistance mechanisms between crop pests and their predators. These mechanisms include several gene/protein families including cytochrome P450s (P450s), ATP binding cassette transporters (ABCs), glutathione S-transferases (GSTs), UDP-glucosyltransferases (UGTs) and carboxyl/cholinesterases (CCEs).Methods and findings: In this study, a high-quality scaffold level de novo genome assembly for O. laevigatus has been generated using a hybrid approach with PacBio long-read and Illumina short-read data. The final assembly achieved a scaffold N50 of 125,649bp and a total genome size of 150.98Mb. The genome assembly achieved a level of completeness of 93.6% using a set of 1,658 core insect genes present as full-length genes. The assembly was annotated with 15,102 protein-coding genes - 87% of which were assigned a putative function - and the resultant gene set achieved a completeness of 84.5%. Comparative analyses revealed gene expansions of sigma class GSTs and CYP3 P450s. Conversely the UGT gene family showed limited expansion. Differences were seen in the distributions of resistance-associated gene families at the subfamily level between O. laevigatus and some of its targeted crop pests. A target site mutation in ryanodine receptors (I4790M, PxRyR) which has strong links to diamide resistance in crop pests and had previously only been identified in lepidopteran species was found to also be present in hemipteran species, including O. laevigatus. Conclusion and significance: This assembly is the first published genome for the Anthocoridae family and will serve as a useful resource for further research into target-site selectivity issues and potential resistance mechanisms in beneficial predators. Furthermore, the expansion of gene families often linked to insecticide resistance may be an indicator of the capacity of this predator to detoxify selective insecticides. These findings could be exploited by targeted pesticide screens and functional studies to increase effectiveness of IPM strategies, which aim to increase crop yields by effectively controlling pests in a sustainable and environmentally-friendly manner, without impacting beneficial predator populations.

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