Growth and development of an invasive forest insect under current and future projected temperature regimes

Walter, Jonathan A.; Thompson, Lily M.; Powers, Sean D.; Parry, Dylan; Agosta, Salvatore J.; Grayson, Kristine L.

doi:10.1002/ece3.9017

Cited by 6 publications

(6 citation statements)

References 77 publications

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“…In contrast with the long‐term Hallmann et al study, our sampling only spanned 3 years, so it suggests that there are important regional differences in ecology (natural or anthropogenic) that are currently influencing insect biomass across North America. One possible explanation for the different responses is that there were different species in the regions we studied (i.e., community composition varies), but studies have also found that even within the same species there can be a local adaptation to temperature that influences population growth rates (e.g., Kingsolver et al, 2011; Porcelli et al, 2017), and therefore abundance and biomass (see also González‐Tokman et al, 2020; Walter et al, 2022).…”

Section: Discussionmentioning

confidence: 99%

Extensive regional variation in the phenology of insects and their response to temperature across North America

Dunn

Ahmed

Armstrong

et al. 2023

Ecology

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Climate change models often assume similar responses to temperatures across the range of a species, but local adaptation or phenotypic plasticity can lead plants and animals to respond differently to temperature in different parts of their range. To date, there have been few tests of this assumption at the scale of continents, so it is unclear if this is a large‐scale problem. Here, we examined the assumption that insect taxa show similar responses to temperature at 96 sites in grassy habitats across North America. We sampled insects with Malaise traps during 2019–2021 (N = 1041 samples) and examined the biomass of insects in relation to temperature and time of season. Our samples mostly contained Diptera (33%), Lepidoptera (19%), Hymenoptera (18%), and Coleoptera (10%). We found strong regional differences in the phenology of insects and their response to temperature, even within the same taxonomic group, habitat type, and time of season. For example, the biomass of nematoceran flies increased across the season in the central part of the continent, but it only showed a small increase in the Northeast and a seasonal decline in the Southeast and West. At a smaller scale, insect biomass at different traps operating on the same days was correlated up to ~75 km apart. Large‐scale geographic and phenological variation in insect biomass and abundance has not been studied well, and it is a major source of controversy in previous analyses of insect declines that have aggregated studies from different locations and time periods. Our study illustrates that large‐scale predictions about changes in insect populations, and their causes, will need to incorporate regional and taxonomic differences in the response to temperature.

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Section: Discussionmentioning

confidence: 99%

Extensive regional variation in the phenology of insects and their response to temperature across North America

Dunn

Ahmed

Armstrong

et al. 2023

Ecology

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“…This indicates that thermal adaptation along the invasion front (i.e. range margin) in addition to their preexisting phenotypic plasticity has fuelled their continued spread and expansion as they have encountered less favourable climates (Faske et al., 2019; Friedline et al., 2019; Thompson et al., 2017, 2021; Walter et al., 2022). However, since we have observed temperature‐related range contractions along the southern invasion front (Tobin et al., 2014), we may be observing the current limits of climate‐related plasticity and evolvability of L. d. dispar .…”

Section: Discussionmentioning

confidence: 99%

Climate‐related variation of metabolic rate across the distribution of a broadly tolerant invasive forest pest

Powers,

Thompson,

Parry

et al. 2024

Journal of Biogeography

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AimMetabolic rate is a widely studied physiological species trait related to energetics, climate, and geographical distributions. Hypotheses have been proposed to explain variation in metabolic rate, but evidence has been mixed due to the limited sampling scope of intraspecific studies. Successful biological invasions offer a unique opportunity to examine the development of intraspecific physiological variation and how it relates to climate, invasive spread and species range limits. The aim of this study was to determine if metabolic rate variation across the spongy moth invasive range was consistent with a pattern of adaptation to local climate.LocationNortheastern United States of America.TaxonLymantria dispar dispar L. (Lepidoptera: Erebidae).MethodsLarvae were sourced from 14 populations across the invasion front and interior of the current L. d. dispar invasive range and were reared at a constant temperature. Routine metabolic rates (RMR) of larvae were assayed at three ecologically relevant temperatures. These data were analysed to determine if there were differences in RMR and temperature sensitivity of RMR among populations. Population‐level variation in RMR was then analysed as a function of local climate and geographical position to test for patterns consistent with local adaptation.ResultsLarval RMR showed significant variation among populations across all assay temperatures, but there was no difference in temperature sensitivity (i.e. slope). This variation followed a positive latitudinal cline with RMR increasing from the southern range to the north. This cline also showed a significant relationship with local climate variables.Main ConclusionsLarval metabolic rate variation was consistent with a pattern of adaptation by L. d. dispar to divergent climates across its invasive range. These results indicated that thermal adaptation of whole‐organism physiology may play a key role in promoting species spread and expansion for biological invasions like L. d. dispar.

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“…The cloned BtCAT amplicons were ligated into the pEASY-T1 vector (TransGen, Beijing, China) and transformed into Escherichia coli Trans1-T1 competent cells (TransGen) for final sequencing. Through sequencing data and genomic data analysis, the exon numbers (10) of BtCATs and the conserved structure of BtCATs were determined (Supporting Information, Fig. S1).…”

Section: Gene Cloningmentioning

confidence: 99%

“…Hightemperature or low-temperature environments can lead to physiological dysfunction and even direct death of insects, ultimately leading to the extinction of populations. 9,10 To maintain normal life activities, insects make a series of physiological metabolic adjustments in response to external temperature stress. [11][12][13] For example, bees sit motionless on the caps of brood cells and regulate the temperature of the brood nest by generating heat.…”

Section: Introductionmentioning

confidence: 99%

Silencing of catalase reduces unfavorable low‐temperature tolerance capacity in whiteflies

Ning,

Liang,

et al. 2024

Pest Management Science

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BACKGROUNDTemperature is a primary factor that determines the eco‐geographical distribution and population development of invasive insects. Temperature stress leads to various negative effects, including excess reactive oxygen species (ROS), and catalase (CAT) is a key enzyme against ROS in the antioxidant pathway. The whitefly Bemisia tabaci MED is a typical invasive pest that causes damage worldwide. Our previous studies have shown that CAT promotes whitefly adaptation to high temperature by eliminating ROS. However, the mechanism underlying the low‐temperature adaptation of whiteflies is still unknown.RESULTSIn this study, we investigated the role of CAT in the low‐temperature tolerance of B. tabaci MED by analyzing its survival rate, reproduction, and ROS levels at 25 °C (as a control, suitable temperature), 20 °C (moderately decreased temperature), and 4 °C (severely decreased temperature). Silencing of BtCAT1, BtCAT2, or BtCAT3 reduced the viability of whiteflies under a short‐term severely decreased temperature (4 °C), which manifested as decreases in survival and fecundity accompanied by significant increases in ROS levels. Moreover, even at a moderately decreased temperature (20 °C), silencing of BtCAT1 led to high ROS levels and low survival rates in adults.CONCLUSIONSilencing of BtCATs significantly increased the sensitivity of B. tabaci MED to low temperatures. BtCAT1 is likely more essential than other BtCATs for low‐temperature tolerance in whiteflies.This article is protected by copyright. All rights reserved.

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Growth and development of an invasive forest insect under current and future projected temperature regimes

Cited by 6 publications

References 77 publications

Extensive regional variation in the phenology of insects and their response to temperature across North America

Extensive regional variation in the phenology of insects and their response to temperature across North America

Climate‐related variation of metabolic rate across the distribution of a broadly tolerant invasive forest pest

Silencing of catalase reduces unfavorable low‐temperature tolerance capacity in whiteflies

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