Mechanisms and Consequences of Partial Migration in Insects

Menz, Myles H. M.; Reynolds, D. R.; Gao, Boya; Hu, Gao; Chapman, Jason W.; Wotton, Karl R.

doi:10.3389/fevo.2019.00403

Cited by 57 publications

(81 citation statements)

References 103 publications

(155 reference statements)

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“…Of note, partial migration, i.e., the migration of a portion of the population while the other part of the population remains resident, also exists in insects [52,53]. In a recent review on partial migration of insects, many of the examples used by the authors correspond to dispersal [54], an aspect that the authors recognized themselves ("Other movement ecology researchers might categorize some of the examples we provide in our review as dispersal instead of migration"); this suggests that the definition of migration in entomological studies is not yet clearly fixed.…”

Section: The Different Terminologies Used For Describing the Movementmentioning

confidence: 99%

A Review of the Phenotypic Traits Associated with Insect Dispersal Polymorphism, and Experimental Designs for Sorting out Resident and Disperser Phenotypes

Renault

2020

Insects

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Dispersal represents a key life-history trait with several implications for the fitness of organisms, population dynamics and resilience, local adaptation, meta-population dynamics, range shifting, and biological invasions. Plastic and evolutionary changes of dispersal traits have been intensively studied over the past decades in entomology, in particular in wing-dimorphic insects for which literature reviews are available. Importantly, dispersal polymorphism also exists in wing-monomorphic and wingless insects, and except for butterflies, fewer syntheses are available. In this perspective, by integrating the very latest research in the fast moving field of insect dispersal ecology, this review article provides an overview of our current knowledge of dispersal polymorphism in insects. In a first part, some of the most often used experimental methodologies for the separation of dispersers and residents in wing-monomorphic and wingless insects are presented. Then, the existing knowledge on the morphological and life-history trait differences between resident and disperser phenotypes is synthetized. In a last part, the effects of range expansion on dispersal traits and performance is examined, in particular for insects from range edges and invasion fronts. Finally, some research perspectives are proposed in the last part of the review.

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Section: The Different Terminologies Used For Describing the Movementmentioning

confidence: 99%

A Review of the Phenotypic Traits Associated with Insect Dispersal Polymorphism, and Experimental Designs for Sorting out Resident and Disperser Phenotypes

Renault

2020

Insects

View full text Add to dashboard Cite

show abstract

“…the migration of a portion of the population while the other part of the population remains resident, also exists in insects [52][53]. In a recent review on partial migration of insects, many of the examples used by the authors correspond to dispersal [54], an aspect that the authors recognized themselves ('Other movement ecology researchers might categorize some of the examples we provide in our review as dispersal instead of migration'); this suggests that the definition of migration in entomological studies is not yet clearly fixed.…”

Section: The Different Terminologies Used For Describing the Movementmentioning

confidence: 99%

A Review on Dispersal Polymorphism in Wing-Dimorphic, Mono-Morphic, Wingless, and Range-Expanding Insects, and Experimental Designs for Sorting out Resident and Disperser Phenotypes

Renault¹

2020

Preprint

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Dispersal represents a key life-history trait with several implications for the fitness of organisms, population dynamics and resilience, local adaptation, meta-population dynamics, range shifting and biological invasions. Plastic and evolutionary changes of dispersal traits have been intensively studied over the past decades in entomology, in particular in wing-dimorphic insects for which literature reviews are available. Importantly, dispersal polymorphism also exists in wing-monomorphic and wingless insects, and except for butterflies, fewer syntheses are available. In this perspective, by integrating the very last research in the fast moving field of insect dispersal ecology, this review article provides an overview of our current knowledge of dispersal polymorphism in insects. After having provided a definition of the main terms characterising insects’ movements, some of the most often used experimental methodologies for the separation of dispersers and residents in wing-monomorphic and wingless insects are presented. The existing knowledge on the morphological and life-history trait differences between resident and disperser phenotypes is then synthetized. The fourth part examines the effects of range expansion on dispersal traits and performance, in particular for insects from range edges and invasion fronts. Finally, some research perspectives are proposed in the last part of the review.

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“…Following conventional guidelines, the threshold for outlier detection were values > 3.5 MAD units from the median were considered as "High Flight Activity" (HFA), as opposed to "Low Flight Activity" (LFA) or short-range flight, which represented values < 3.5 MAD units. Unless a population is observed to be "on the move" as are migratory swarms of locusts (Kennedy, 1951) or monarch butterflies (Gibo and Pallett, 1979), it is generally assumed that at any moment the fraction of individuals that express migratory behavior is small (Dingle and Arora 1973;Taylor et al 1992;Taylor, Nault, and Styer 1993;Taylor et al 2010;Lee and Leskey 2015;Menz et al 2019). This assumption relies on Mark-Release-Recapture (MRR) studies suggesting that a sizeable proportion of the population remain near the area where they were marked, and also that the duration of the migratory phase last a few days and is typically shorter than the non-migratory phase, which can last several weeks or months (Johnson, 1969;Roff and Fairbairn, 2007).…”

Section: Data Processing and Analysismentioning

confidence: 99%

Quantifying flight aptitude variation in wildA. gambiaes.l. in order to identify long-distance migrants

Faiman

Yaro

Diallo

et al. 2020

Preprint

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BackgroundIn the West African Sahel, during the 5-7 month-long dry season mosquito reproduction is halted due to the absence of surface waters required for larval development.Recent studies have suggested that both Anopheles gambiae s.s and A. arabiensis persist in this region by migration from distant locations where larval sites are perennial, and A. coluzzii engages in long-distance migration, presumably within the Sahel, following shifting resources due to the ever-changing patterns of Sahelian rainfall. Understanding mosquito migration is key to malaria control, a disease that still kills >400,000 people, mostly children in Africa. Methods We used a new tethered-flight assay to characterize flight in the three primary malaria vectors mentioned above and evaluated seasonal differences in their flight activity. The flight of tethered wild mosquitoes was audio-recorded from 21:00h to 05:00h in the following morning and three flight aptitude indices were examined: total flight duration, longest flight bout, and the number of flight bouts during the assay. Based on recent studies, we predicted that (i) the distribution of the flight aptitude indices would exhibit bi-modality and/or marked skewness, indicating a subpopulation of high flight activity (HFA) associated with long-distance migrants, in contrast to low flight activity (LFA) in appetitive flyers. Additionally, flight aptitude would (ii) increase in the wet season, (iii) increase in gravid females, and (iv) vary among the vector species.Results The distributions of all flight indices departed sharply from a normal curve, and were strongly skewed to the right, consistent with the division of the population into a majority of LFAs and a minority of HFAs, e.g., the median total flight was 586 seconds, and its maximum value was 16,110 seconds (~4.5 h). As predicted, flight aptitude peaked in the wet season and was higher in gravid females than in non-bloodfed females. Flight aptitude was higher in A. coluzzii than in A. arabiensis, but A. gambiae s.s. was not statistically different from either. We evaluated differences in wing size and shape between LFAs and HFAs. During the wet season, wing size of HFA A. coluzzii was larger than that of LFAs; it was wider than predicted by its length, indicating a shape change. However, no statistically significant differences were found in wings of A. gambiae s.s. or A. arabiensis. ConclusionsThe partial agreement between the assay results and predictions suggest a degree of discrimination between appetitive flyers and long-distance migrants. Wing size and shape seems to indicate higher flight activity in A. coluzzii during the wet season.

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Mechanisms and Consequences of Partial Migration in Insects

Cited by 57 publications

References 103 publications

A Review of the Phenotypic Traits Associated with Insect Dispersal Polymorphism, and Experimental Designs for Sorting out Resident and Disperser Phenotypes

A Review of the Phenotypic Traits Associated with Insect Dispersal Polymorphism, and Experimental Designs for Sorting out Resident and Disperser Phenotypes

A Review on Dispersal Polymorphism in Wing-Dimorphic, Mono-Morphic, Wingless, and Range-Expanding Insects, and Experimental Designs for Sorting out Resident and Disperser Phenotypes

Quantifying flight aptitude variation in wildA. gambiaes.l. in order to identify long-distance migrants

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