Large-scale genetic admixture suggests high dispersal in an insect pest, the apple fruit moth

Elameen, Abdelhameed; Klütsch, Cornelya F. C.; Fløystad, Ida; Knudsen, Geir; Hagen, Snorre B.; Eiken, Hans Geir

doi:10.1371/journal.pone.0236509

Cited by 8 publications

(7 citation statements)

References 87 publications

(154 reference statements)

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“…In heavy intermast years, the apple fruit moth can hatch to find no host material available and will therefore seek secondary hosts, causing serious damage to apple crops [ 27 ]. A. conjugella is known to have high genetic diversity and a wide distribution in Fennoscandia [ 28 – 30 ], but the lack of complete mitogenomes for A. conjugella and the family Argyresthiidae hampers further studies on systematics, population genetics, taxonomy and evolutionary biology.…”

Section: Introductionmentioning

confidence: 99%

Novel insight into lepidopteran phylogenetics from the mitochondrial genome of the apple fruit moth of the family Argyresthiidae

Elameen,

Maduna,

Mageroy

et al. 2024

BMC Genomics

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Background The order Lepidoptera has an abundance of species, including both agriculturally beneficial and detrimental insects. Molecular data has been used to investigate the phylogenetic relationships of major subdivisions in Lepidoptera, which has enhanced our understanding of the evolutionary relationships at the family and superfamily levels. However, the phylogenetic placement of many superfamilies and/or families in this order is still unknown. In this study, we determine the systematic status of the family Argyresthiidae within Lepidoptera and explore its phylogenetic affinities and implications for the evolution of the order. We describe the first mitochondrial (mt) genome from a member of Argyresthiidae, the apple fruit moth Argyresthia conjugella. The insect is an important pest on apples in Fennoscandia, as it switches hosts when the main host fails to produce crops. Results The mt genome of A. conjugella contains 16,044 bp and encodes all 37 genes commonly found in insect mt genomes, including 13 protein-coding genes (PCGs), two ribosomal RNAs, 22 transfer RNAs, and a large control region (1101 bp). The nucleotide composition was extremely AT-rich (82%). All detected PCGs (13) began with an ATN codon and terminated with a TAA stop codon, except the start codon in cox1 is ATT. All 22 tRNAs had cloverleaf secondary structures, except trnS1, where one of the dihydrouridine (DHU) arms is missing, reflecting potential differences in gene expression. When compared to the mt genomes of 507 other Lepidoptera representing 18 superfamilies and 42 families, phylogenomic analyses found that A. conjugella had the closest relationship with the Plutellidae family (Yponomeutoidea-super family). We also detected a sister relationship between Yponomeutoidea and the superfamily Tineidae. Conclusions Our results underline the potential importance of mt genomes in comparative genomic analyses of Lepidoptera species and provide valuable evolutionary insight across the tree of Lepidoptera species.

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Section: Introductionmentioning

confidence: 99%

Novel insight into lepidopteran phylogenetics from the mitochondrial genome of the apple fruit moth of the family Argyresthiidae

Elameen,

Maduna,

Mageroy

et al. 2024

BMC Genomics

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show abstract

“…In heavy intermast years, the apple fruit moth can hatch to nd no host material available and will therefore seek secondary hosts, causing serious damage to apple crops [27]. A. conjugella is known to have high genetic diversity and a wide distribution in Fennoscandia [28][29][30], but the lack of complete mitogenomes for A. conjugella and the family Argyresthiidae hampers further studies on systematics, population genetics, taxonomy and evolutionary biology.…”

Section: Introductionmentioning

confidence: 99%

Novel insight in Lepidoptera phylogenetics from the mitochondrial genome of the apple fruit moth of the family Argyresthiidae

Elameen

Maduna

Magerøy

et al. 2023

Preprint

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Background The order Lepidoptera has an abundance of species, including both agriculturally beneficial and detrimental insects. Based on molecular data, the phylogenetic relationships of the major subdivisions of Lepidoptera have been investigated, contributing to the understanding of the evolutionary relationships at the superfamily and family levels. However, the phylogenetic placement of many superfamilies and/or families in this order is still unknown. In this study, we determine the systematic status of the family Argyresthiidae within Lepidoptera and explore its phylogenetic affinities and implications for the evolution of the order. We describe the first mitochondrial (mt)genome from a member of Argyresthiidae, the apple fruit moth Argyresthia conjugella. The insect is an important pest on apples in Fennoscandia, as it switches hosts when the main host fails to produce crops. Results The mt genome of A. conjugella contains 16,044 bp and encodes all 37 genes generally found in insect mt genomes, including 13 protein-coding genes (PCGs), two ribosomal RNAs, 22 transfer RNAs, and a large control region (1101 bp). The nucleotide composition was extremely AT-rich (82%). All detected PCGs (13) began with an ATN codon and terminated with a TAA stop codon, except the start codon in cox1 is ATT. All 22 tRNAs had cloverleaf secondary structures, except tRNAS1, where one of the dihydrouridine (DHU) arms is missing, reflecting potential differences in gene expression. When compared to the mt genomes of 507 other Lepidoptera representing 18 superfamilies and 42 families, phylogenomic analyses found that A. conjugella had the closest relationship with the Plutellidae family (Yponomeutoidea-super family). We also detected a sister relationship between Yponomeutoidea and the superfamily Tineidae. Conclusions Our results underline the potential importance of mt genomes in comparative genomic analyses of Lepidoptera species and provide robust evolutionary insight across the tree of Lepidoptera species.

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“…Insect pests are abundant in all agricultural regions of the world, and many are difficult to control due to their rapid development of insecticide resistance and active migration. For these pests, molecular evidence of genetic pattern and gene flow may provide important guidance in understanding the colonization history ( Yang et al, 2012 ; Kirk et al, 2013 ; Cao et al, 2019 ; You et al, 2020 ), tracking insecticide resistance ( Taylor et al, 2021 ), and investigating metapopulation dynamics ( Dinsdale et al, 2012 ; Elameen et al, 2020 ; Perera et al, 2020 ). Much work has been done on the genetic structure and phylogeography of widely distributed insect pests, such as Locusta migratoria ( Ma et al, 2012 ), Frankliniella occidentalis ( Yang et al, 2012 ; Cao et al, 2019 ), Nilaparvata lugens (Stål) ( Hu et al, 2019 ) and Plutella xylostella ( You et al, 2020 ).…”

Section: Introductionmentioning

confidence: 99%

“…Unlike vertebrate migrants, migration circuits of insects can involve multiple generations and experience different levels of connectivity due to their shorter generation time and lower degree of control over movement (flight) directions (Gao et al, 2020). Most population genetic studies of highly dispersive species report a pattern of low genetic differentiation and high gene flow (Jiang et al, 2010;Wei et al, 2013;Elameen et al, 2020), which is not unexpected, but not informative. This is due to the frequently applied genetic parameter N m refers to historical gene flow and thus inadequate for contemporary population dynamics.…”

Section: Introductionmentioning

confidence: 99%

Temporal sampling and network analysis reveal rapid population turnover and dynamic migration pattern in overwintering regions of a cosmopolitan pest

Vasseur

et al. 2022

Front. Genet.

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Genetic makeup of insect pest is informative for source-sink dynamics, spreading of insecticide resistant genes, and effective management. However, collecting samples from field populations without considering temporal resolution and calculating parameters related to historical gene flow may not capture contemporary genetic pattern and metapopulation dynamics of highly dispersive pests. Plutella xylostella (L.), the most widely distributed Lepidopteran pest that developed resistance to almost all current insecticides, migrates heterogeneously across space and time. To investigate its real-time genetic pattern and dynamics, we executed four samplings over two consecutive years across Southern China and Southeast Asia, and constructed population network based on contemporary gene flow. Across 48 populations, genetic structure analysis identified two differentiated insect swarms, of which the one with higher genetic variation was replaced by the other over time. We further inferred gene flow by estimation of kinship relationship and constructed migration network in each sampling time. Interestingly, we found mean migration distance at around 1,000 km. Such distance might have contributed to the formation of step-stone migration and migration circuit over large geographical scale. Probing network clustering across sampling times, we found a dynamic P. xylostella metapopulation with more active migration in spring than in winter, and identified a consistent pattern that some regions are sources (e.g., Yunnan in China, Myanmar and Vietnam) while several others are sinks (e.g., Guangdong and Fujian in China) over 2 years. Rapid turnover of insect swarms and highly dynamic metapopulation highlight the importance of temporal sampling and network analysis in investigation of source-sink relationships and thus effective pest management of P. xylostella, and other highly dispersive insect pests.

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Large-scale genetic admixture suggests high dispersal in an insect pest, the apple fruit moth

Cited by 8 publications

References 87 publications

Novel insight into lepidopteran phylogenetics from the mitochondrial genome of the apple fruit moth of the family Argyresthiidae

Novel insight into lepidopteran phylogenetics from the mitochondrial genome of the apple fruit moth of the family Argyresthiidae

Novel insight in Lepidoptera phylogenetics from the mitochondrial genome of the apple fruit moth of the family Argyresthiidae

Temporal sampling and network analysis reveal rapid population turnover and dynamic migration pattern in overwintering regions of a cosmopolitan pest

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