Hostname: page-component-7bb8b95d7b-lvwk9 Total loading time: 0 Render date: 2024-09-25T03:50:15.079Z Has data issue: false hasContentIssue false
  • English
  • Français

Ontogenetic responses of physiological fitness in Spodoptera frugiperda (Lepidoptera: Noctuidae) in response to repeated cold exposure

Published online by Cambridge University Press:  04 April 2023

Abongile Mbande ,
Reyard Mutamiswa  and
Frank Chidawanyika Open the ORCID record for Frank Chidawanyika [Opens in a new window]
Abongile Mbande
Affiliation:
Department of Zoology and Entomology, University of the Free State, Bloemfontein, South Africa
Reyard Mutamiswa
Affiliation:
Department of Zoology and Entomology, University of the Free State, Bloemfontein, South Africa Tugwi-Mukosi Multidisciplinary Research Institute, Midlands State University, Gweru, Zimbabwe Department of Zoology and Entomology, Rhodes University, Makhanda, South Africa
Frank Chidawanyika*
Affiliation:
Department of Zoology and Entomology, University of the Free State, Bloemfontein, South Africa International Centre of Insect Physiology and Ecology (ICIPE), Nairobi, Kenya
*
Author for correspondence: Frank Chidawanyika, Email: fchidawanyika@icipe.org
Rights & Permissions [Opens in a new window]

Abstract

In this era of global climate change, intrinsic rapid and evolutionary responses of invasive agricultural pests to thermal variability are of concern given the potential implications on their biogeography and dire consequences on human food security. For insects, chill coma recovery time (CCRT) and critical thermal minima (CTmin), the point at which neuromuscular coordination is lost following cold exposure, remain good indices for cold tolerance. Using laboratory-reared Spodoptera frugiperda (Lepidoptera: Noctuidae), we explored cold tolerance repeated exposure across life stages of this invasive insect pest. Specifically, we measured their CTmin and CCRT across four consecutive assays, each 24 h apart. In addition, we assessed body water content (BWC) and body lipid content (BLC) of the life stages. Our results showed that CTmin improved with repeated exposure in 5th instar larvae, virgin males and females while CCRT improved in 4th, 5th and 6th instar larvae following repeated cold exposure. In addition, the results revealed evidence of cold hardening in this invasive insect pest. However, there was no correlation between cold tolerance and BWC as well as BLC. Our results show capacity for cold hardening and population persistence of S. frugiperda in cooler environments. This suggests potential of fall armyworm (FAW) to withstand considerable harsh winter environments typical of its recently invaded geographic range in sub-Saharan Africa.

Keywords

Climate changefall armywormplasticity-tradeoffthermal tolerance
Type
Research Paper
Information
Bulletin of Entomological Research , Volume 113 , Issue 4 , August 2023 , pp. 449 - 455
Check for updates
Copyright
Copyright © International Centre of Insect Physiology and Ecology, 2023. Published by Cambridge University Press

Introduction

Repeatability or reproducibility experiments are profound tools that were originally developed for independent testing of the precision of experimental protocols. In biological research, the repeatability of observational data can be used to track organismal plastic and genetic responses to stress factors at the individual or population level at various temporal scales (Avargues-Weber et al., Reference Avargues-Weber, Lihoreau, Isabel and Giurfa2015; Niemelä and Dingemanse, Reference Niemelä and Dingemanse2017; Näslund, Reference Näslund2021). Given the escalated attention on climate change in recent years, repeatability studies (though controversial) can be pivotal in investigating basal and plasticity of thermal tolerance (Morgan et al., Reference Morgan, Finnøen and Jutfelt2018; O'Donnell et al., Reference O'Donnell, Regish, McCormick and Letcher2020; O'Neill et al., Reference O'Neill, Davis and MacMillan2021) where both environmental and genetic phenotypic variation effects can be used to determine within-individual trait variability (Grinder et al., Reference Grinder, Bassar and Auer2020). If the thermal tolerance of a tested organism is consistent over time, denoting high repeatability, it indicates that the adaptive potential of the trait is high while the converse is true for low repeatability (Morgan et al., Reference Morgan, Finnøen and Jutfelt2018).

For insects, body temperature depends on ambient conditions mediating biochemical and physiological processes therein (Chown and Nicolson, Reference Chown and Nicolson2004; Sinclair et al., Reference Sinclair, Alvarado and Ferguson2015). Subsequently, such organismal responses mediate development and can cascade to population level through factors such as seasonality, geographic distribution and voltinism (Du Plessis et al., Reference Du Plessis, Schlemmer and Van den Berg2020; Phophi et al., Reference Phophi, Mafongoya and Lottering2020; Tarusikirwa et al., Reference Tarusikirwa, Mutamiswa, Chidawanyika and Nyamukondiwa2020; Nyamukondiwa et al., Reference Nyamukondiwa, Machekano, Chidawanyika, Mutamiswa, Ma and Ma2022). Of interest is how the magnitude and frequency of thermal extremes in the form of heat waves and cold snaps wrought by the changing climates influence pest physiology, survival and key life-history traits (Tollefson, Reference Tollefson2014) as it has direct implications on their population dynamics (Chidawanyika et al., Reference Chidawanyika, Mudavanhu and Nyamukondiwa2012, Reference Chidawanyika, Chikowore and Mutamiswa2020) and ultimately food security (Gregory et al., Reference Gregory, Johnson, Newton and Ingram2009). Thus, apart from magnitude of thermal exposure, insects experience different mode of thermal fluctuations (e.g. acute vs. chronic, rapid vs. slow fluctuations and/or repeated exposures) typical of diel and seasonal changes (Colinet et al., Reference Colinet, Nguyen, Cloutier, Michaud and Hance2007). Such extremes, and not average temperatures drive several organismal responses including evolutionary adaptations within and across generations (Cox et al., Reference Cox, Schubert, Travisano and Putonti2010; Travis Reference Travis2014; Buckley and Huey, Reference Buckley and Huey2016) and define geographic ranges via various demographic tipping points (Lynch et al., Reference Lynch, Rhainds, Calabrese, Cantrell, Cosner and Fagan2014).

Indeed, insects have evolved diverse morphological, physiological and behavioural adaptations to withstand and colonize otherwise lethal novel environments (Bale, Reference Bale2002; Neal et al., Reference Neal, Diaz, Qureshi and Cave2021). For example, overwintering insects are known to survive stressful low temperatures through employing cold tolerance strategies such as rapid cold hardening (RCH), freeze tolerance and freeze avoidance (Sinclair et al., Reference Sinclair, Alvarado and Ferguson2015; Feng et al., Reference Feng, Zhang, Li, Yang and Zong2018). Freeze-tolerant insects survive intracellular ice formation through use of cryoprotectants, removal of ice nucleators and anti-freeze heat shock proteins synthesis (Elnitsky et al., Reference Elnitsky, Hayward, Rinehart, Denlinger and Lee2008; Storey and Storey, Reference Storey and Storey2012; Toxopeus et al., Reference Toxopeus, Koštál and Sinclair2019). On the contrary, freeze-intolerant/avoidant insects cannot withstand internal ice formation but survive through keeping their body fluids under a supercooled condition (Sinclair et al., Reference Sinclair, Alvarado and Ferguson2015; Andreadis and Athanassiou, Reference Andreadis and Athanassiou2017). RCH, a form of phenotypic plasticity, confers survival advantages at low lethal temperature after brief pre-treatment to a prior sub-lethal temperature shock (Lee et al., Reference Lee, Chen and Denlinger1987; Teets and Denlinger, Reference Teets and Denlinger2013). Over longer time scales such prior exposure to sublethal temperatures also confer advantages to identical future identical thermal stress in what is referred to as beneficial acclimation (Leroi et al., Reference Leroi, Bennett and Lenski1994).

In nature, insects may thus face multiple stressors including repeated cold stress during diel and seasonal thermal fluctuations (Marshall and Sinclair, Reference Marshall and Sinclair2010) where the above-mentioned plastic responses play a role (Nyamukondiwa et al., Reference Nyamukondiwa, Chidawanyika, Machekano, Mutamiswa, Sands, Mgidiswa and Wall2018). Mimicking such repeated thermal exposure in manipulative experiments allows investigation of the relationship between repeatability and adaptive responses (Boake, Reference Boake1989; Morgan et al., Reference Morgan, Finnøen and Jutfelt2018; Grinder et al., Reference Grinder, Bassar and Auer2020). In this study, we used common measures of cold tolerance in critical thermal minimum (CTmin) and chill coma recovery time (CCRT) as proxies for cold hardiness (Andersen et al., Reference Andersen, Manenti, Sørensen, MacMillan, Loeschcke and Overgaard2015; Mutamiswa et al., Reference Mutamiswa, Machekano, Chidawanyika and Nyamukondiwa2018, Reference Mutamiswa, Machekano, Chidawanyika and Nyamukondiwa2019; Izadi et al., Reference Izadi, Mohammadzadeh and Mehrabian2019).

CTmin is an organism's lower thermal tolerance limit where an insect is incapacitated due to compromised neuromuscular activity (Sinclair et al., Reference Sinclair, Alvarado and Ferguson2015; Izadi et al., Reference Izadi, Mohammadzadeh and Mehrabian2019). If low temperature conditions persist, CTmin is followed by chill coma where paralysis due to complete loss of neuromuscular function occurs (Hazell and Bale, Reference Hazell and Bale2011; O'Neill et al., Reference O'Neill, Davis and MacMillan2021). The time that an insect requires to regain neuromuscular function following chill coma is what is then regarded as CCRT (Sinclair et al., Reference Sinclair, Alvarado and Ferguson2015). Given their ubiquitous occurrence in nature and capacity to define limits for organismal activity, these key indices provide valuable ecologically relevant measures of insect cold tolerance. Thus, understanding the evolutionary capacity following repeated exposure provides important information on their adaptive capacity and potential geographic range expansion in invasive insects such as Spodoptera frugiperda.

S. frugiperda is a highly invasive insect pest native to the tropics and sub-tropics of America (Goergen et al., Reference Goergen, Kumar, Sankung, Togola and Tamò2016). The larvae of this polyphagous insect cause significant economic losses in several important crops but inflict the most damage in the Poaceae family (Lu and Adang, Reference Lu and Adang1996; Nboyine et al., Reference Nboyine, Kusi, Abudulai, Badii, Zakaria, Adu, Haruna, Seidu, Osei, Alhassan and Yahaya2020). In Africa, S. frugiperda was first detected in Nigeria before rapidly spreading to 47 countries across the African continent (Goergen et al., Reference Goergen, Kumar, Sankung, Togola and Tamò2016; Cock et al., Reference Cock, Beseh, Buddie, Cafá and Crozier2017; Early et al., Reference Early, González-Moreno, Murphy and Day2018; Nboyine et al., Reference Nboyine, Kusi, Abudulai, Badii, Zakaria, Adu, Haruna, Seidu, Osei, Alhassan and Yahaya2020). It is highly destructive to maize, Zea mays, which is a staple food in many parts of Africa (Day et al., Reference Day, Abrahams, Bateman, Beale, Clottey, Cock, Colmenarez, Corniani, Early, Godwin and Gomez2017; Kasoma et al., Reference Kasoma, Shimelis and Laing2021).

S. frugiperda does not diapause, instead it is known to migrate to environments with favourable conditions for survival (Du Plessis et al., Reference Du Plessis, Schlemmer and Van den Berg2020; Vatanparast and Park, Reference Vatanparast and Park2022). It has been reported to survive in Africa, all year-round due to prevailing conducive biophysical environment (Early et al., Reference Early, González-Moreno, Murphy and Day2018; Du Plessis et al., Reference Du Plessis, Schlemmer and Van den Berg2020; Keosentse et al., Reference Keosentse, Mutamiswa, Du Plessis and Nyamukondiwa2021). The upregulation of glycerol-3-phosphate dehydrogenase and glycerol kinase genes for increased synthesis of the cryoprotectant glycerol has been attributed to the key physiological response to withstand cold environments in S. frugiperda (Vatanparast and Park, Reference Vatanparast and Park2022). However, survival has been reported to be limited in some cases in Asia where harsh winters decimate seasonal populations while annual reinvasions provide new propagules (Vatanparast and Park, Reference Vatanparast and Park2022). Nevertheless, little is known about the role of acquired/induced cold tolerance in the fitness of S. frugiperda following prior exposure. Yet, induced cold tolerance can play a key role in preserving and improving key life-history activities at acute temporal scales.

Here, we examined the consequences of repeated cold exposure on low thermal tolerance (CTmin and CCRT) of S. frugiperda life stages across 72 h. We hypothesized that CTmin and CCRT are repeatable traits and may change over time because of cold hardening. Since body water and lipid content is associated with basal and induced cold tolerance in insects (or lack thereof), we subsequently assessed the two parameters following thermal exposure to draw inferences on the performance of S. frugiperda and subsequent management.

Materials and methods

Insect culture and maintenance

The initial colony of S. frugiperda was obtained as larvae from the Agricultural Research Council, Plant Health Protection (ARC-PHP) Pretoria, South Africa. Thereafter, the insects were maintained on an artificial diet in the insectary under optimum conditions of 28°C, 65 ± 5% relative humidity (RH) and 12L:12D photoperiod. Since cannibalism is reportedly predominant among late larval instars (Chapman et al., Reference Chapman, Williams, Escribano, Caballero, Cave and Goulson1999), each third instar larva was individually placed in a separate 100 ml plastic vial with perforated screw-cap lid and soybean wheat germ artificial diet (Southland Products Inc., Lake Village, Arkansas, USA) until pupation. Pupae were maintained in open Petri dishes (30 × 30 × 30 cm3) in collapsible rearing cages made of mesh cloth until adult eclosion. Adults were provided with 25% sugar-water from a moistened cotton wool placed in a Petri dish. At least two maize plants (3–4 weeks old) were placed in each rearing cage as oviposition substrate for gravid females. After hatching, the 1st instar larvae were transferred to an artificial diet for subsequent rearing. For all the experiments F1 generation of 4th, 5th, 6th instar larvae and 24–48 h old virgin adults were used.

CTmin and repeated cold exposure assays

To the relationship between CTmin and repeated cold exposure, larvae and adults (males and females) of S. frugiperda underwent repeated cold tolerance (CTmin) assays at 0 (control), 24, 48 and 72 h intervals. CTmin were assayed using standardized dynamic and ecologically relevant protocols (Chidawanyika and Terblanche, Reference Chidawanyika and Terblanche2011; Chidawanyika et al., Reference Chidawanyika, Nyamukondiwa, Strathie and Fischer2017). Ten replicate larvae and adults were individually placed randomly in a series of 200 mm glass tubes (‘organ pipes’) connected to an insulated double-jacketed chamber linked to a programmable water bath (Grant model Tx150; Grant Instruments, UK) filled with 1:1 water:propylene glycol. In the ‘organ pipes’, insects were allowed to equilibrate for 10 min at 28°C (optimum temperature) before decreasing the temperature at a rate of 0.25°C min−1 until their CTmin were recorded. This was repeated twice for each life stage to yield sample sizes of n = 20 per treatment. To record chamber temperature, a thermocouple (type K 36 SWG) connected to a digital thermometer (53/54IIB, Fluke Cooperation, Everett, Washington, USA) was inserted into a control (centre) glass tube of the organ pipes. After each assay, insects were given time to recover before repeating the same assay across 24, 48 and 72 h intervals using the same batch of insects. CTmin was considered as the temperature at which insects did not respond to gentle prodding (e.g. Nyamukondiwa and Terblanche Reference Nyamukondiwa and Terblanche2009).

Influence of repeated cold exposure on CCRT

CCRT was assessed following Mutamiswa et al. (Reference Mutamiswa, Machekano, Chidawanyika and Nyamukondiwa2018). A total of ten replicate larvae and adults were placed individually in 7 ml screw-cap glass vials with 1 mm diameter holes pierced through cap for ventilation. The vials were then placed into a large zip-lock bag which was subsequently submerged into a water bath (Grant LTC40 model TX150) filled with a 1:1 water:propylene glycol mixture and set at 0°C for 1 h. After 1 h at chill-coma temperature, the tubes were removed from the water bath and transferred to a Memmert climate chamber (HPP 260, Memmert GmbH+ Co.KG, Schwabach, Germany) set at 28°C, 65% RH for recovery. The chamber was connected to a camera (HD Covert Network Camera, DS-2CD6412FWD-20, Hikvision Digital Technology Co., Ltd, Hangzhou, Zhejiang, China) that was linked to a computer where observations were recorded. This was repeated twice for each life stage to yield sample sizes of n = 20 per treatment. After each assay, insects were exposed to the same treatment and CCRT measured across 24, 48 and 72 h intervals using the same batch of insects. CCRT was defined as the time (in min) required for an adult to stand upright on its legs (Milton and Partridge, Reference Milton and Partridge2008).

Determination of body water content (BWC)

After 72 h interval following CTmin and repeated cold exposure assays, BWC of the insects were determined. Larvae (4th, 5th and 6th instar) and adults were individually placed in a pre-weighed 50 ml Eppendorf tubes and the initial mass of each insect before oven drying was measured (to 0.0001 g) on a Scout Pro (DHAUS) microbalance (model: Scout Pro SPU 123, Parsippany, USA). Thereafter, insects were placed in a Memmert drying oven (UL50, Memmert, Schwabach, Germany) set at 60°C for 72 h. Insects were allowed to cool under laboratory temperature conditions of 28°C for 30 min thereafter, dry mass was measured (to 0.0001 g) on a microbalance. To determine BWC, dry mass was subtracted from the initial mass following Bazinet et al. (Reference Bazinet, Marshall, Macmillan, Williams and Sinclair2010) and Weldon et al. (Reference Weldon, Nyamukondiwa, Karsten, Chown and Terblanche2018).

Determination of body lipid content (BLC)

Following BWC assays, the tested insects were further oven dried for another 72 h at 60°C. Thereafter, the insects were individually washed in 1.5 ml diethyl ether and then gently agitated at 250 rpm for 24 h at 37°C using ST 5 CAT orbital shaker (model: Zipperer GmbH, D 79219 Staufen, Germany) following the methods of Mitchell et al., (Reference Mitchell, Boardman, Clusella-Trullas and Terblanche2017). The diethyl ether was then removed from the tubes and insects were oven dried again at 60°C for 24 h, before reweighing. The lipid content for each individual was calculated by subtracting the lipid-free dry mass from the initial dry mass. Controls were exposed to the same conditions before measuring their lipid content.

Data analysis

Data analyses were carried out in STATISTICA, 13.5.0 version (Statsoft Inc., 2021) and R version 4.1.2 (R Development Core Team, 2021). Normality and equality of variances were first checked using the Shapiro–Wilk and Hartley–Bartlett tests, respectively. Data for CCRT was linear and met the conditions for normality and equality of variances (W = 0.83, P = 0.12) and were analysed using generalized linear models assuming a Gaussian distribution and an identity link function in R. The CTmin data also met the linear model assumptions and were analysed using repeated measures analysis of variance. Tukey–Kramer's post-hoc tests were used to separate statistically heterogeneous means. The relationship between CTmin and BWC and BLC were examined using linear regression in STATISTICA.

Results

CTmin and repeated cold exposure assays

CTmin significantly varied across life stages following repeated cold exposure (F 16, 282 = 134.59, P < 0.001) (fig. 1). In 5th instar and virgin adults, cold tolerance (CTmin) improved with repeated cold exposure (fig. 1). However, 6th instar larvae showed compromised cold tolerance with CTmin increasing with repeated exposure (fig. 1). Virgin females recorded the lowest CTmin across all assays relative to other life stages (fig. 1).

Figure 1. CTmin in adult (virgin male and female) and larval stages of S. frugiperda following repeated cold exposure. Data points represent means of n = 20 while error bars denote 95% confidence limits for each gender and life stage. Different letters above error bars denote significant differences.

CCRT and repeated cold exposure assays

As in CTmin assays, CCRT varied significantly across life stages with repeated cold exposure (F 16, 282 = 4.06, P < 0.001) (fig. 2). CCRTs of tested instars (4th, 5th and 6th instar) decreased with repeated cold exposure (fig. 2). In adults (virgin males and females), CCRT improved following repeated exposure at 24 h interval and was compromised after 48 and 72 h intervals (fig. 2).

Figure 2. CCRT in adult (virgin male and female) and larval stages of S. frugiperda following repeated cold exposure. Data points represent means of n = 20 while error bars denote 95% confidence limits for each gender and life stage. Different letters above error bars denote significant differences.

Body water and lipid content

BWC did not vary significantly among life stages (F 4, 95 = 2.01, P = 0.98) (fig. 3A). There was no significant difference in BWC between all tested life stages (fig. 3A). Nevertheless, BWC was not significantly correlated with low temperature tolerance (measured as CTmin) (fig. 3B).

Figure 3. BWC (g) across different life stages (A) and relationship between BWC and CTmin (B) in S. frugiperda.

Similar to BWC, BLC did not significantly vary among life stages (F 4, 95 = 2.94, P = 0.24) (fig. 4A). As in BWC, BLC was not significantly correlated with low temperature tolerance such that CTmin decreased with BLC (fig. 4B).

Figure 4. BLC (g) across different life stages (A) and the relationship between BLC and CTmin (B) in S. frugiperda.

Discussion

Insect physiological and behavioural adaptations are very important for determining survival and population dynamics in both transient and seasonal cold spells (Chown and Nicolson, Reference Chown and Nicolson2004; Terblanche et al., Reference Terblanche, Hoffmann, Mitchell, Rako, le Roux and Chown2011; Andrew and Kemp, Reference Andrew and Kemp2016). As expected, our results showed that repeated cold exposure influences the fitness of S. frugiperda (determined as CTmin and CCRT). While insects may face multiple temperature variabilities in winter season, the repeated cold exposures can trigger responses that may set the insect on a different physiological path relative to a single exposure (Marshall and Sinclair, Reference Marshall and Sinclair2010, Reference Marshall and Sinclair2012). In the current study, CTmin improved with repeated exposure in 5th instar larvae, virgin males and females in agreement with Renault et al. (Reference Renault, Nedved, Hervant and Vernon2004) who reported improved survival in beetles that were exposed to repeated cold exposure. A similar trend was reported in Drosophila melanogaster, with low temperature tolerance improving following repeated cold exposure in tested insects (Le Bourg, Reference Le Bourg2007). However, compromised and fluctuating CTmin were recorded in 6th instar and 4th instar larvae, respectively. Given this variation across life stages, it therefore indicates that repeated thermal exposure impacts on CTmin are life-stage dependent. While 5th instar larvae, virgin males and females showed enhanced CTmin across subsequent exposures, virgin females recorded the lowest CTmin across treatment intervals indicating that they were the most thermally tolerant. This gives them a fitness and survival advantage when they encounter extreme cold conditions in nature.

In the present study, repeated thermal exposure improved CCRT in 4th, 5th and 6th instar larvae and this is in consonance with Andersen et al. (Reference Andersen, Folkersen, MacMillan and Overgaard2017) who reported improved chill-coma recovery, cellular survival and cold tolerance in Locusta migratoria following brief cold exposure periods. However, compromised CCRTs were recorded in adults (males and females) in keeping with van Dooremalen et al. (Reference van Dooremalen, Suring and Ellers2011) who reported CCRT decrease in Orchesella cincta following repeated cold exposure. The variations in the current study underlie that CCRT responses are life-stage dependent. Although CCRT and CTmin are measures of cold tolerance, surprisingly, 6th instar larvae recorded compromised CTmin and enhanced CCRT indicating that responses also vary across traits, thus can be trait dependent.

The changes in cold tolerance across consecutive measurements provide insight into potential benefits of short-term acclimation to extreme cold events through cold hardening. Our results showed evidence of cold hardening in S. frugiperda as indicated by improved cold tolerance in some of the life stages. This suggests significant adaptive potential for cold tolerance in this invasive insect species and that individuals may also respond directly to low temperature extremes through phenotypic plasticity. While S. frugiperda has been reported to overwinter and survive all year round in Africa (Kebede and Shimalis, Reference Kebede and Shimalis2018; Prasanna et al., Reference Prasanna, Huesing and Peschke2018; Keosentse et al., Reference Keosentse, Mutamiswa, Du Plessis and Nyamukondiwa2021), the results indicate its potential to adapt to variable thermal extremes in winter and this may give it fitness and survival advantage in the face of climate change. Insects reportedly enhance their cold tolerance through carbohydrate cryoprotectants accumulation, antifreezes synthesis, lipid membranes reordering and either removal (freeze avoiding) or retaining (freeze tolerant) of ice nucleators (Lee, Reference Lee, Denlinger and Lee2010). Therefore, differential life-stage responses shown in this study following repeated exposure assays may be a result of variation in these physiological components of cold hardiness. However, this warrants further investigation to fully elucidate the responses.

Cold tolerance is dependent on the water content remaining unfrozen in many cold hardened insects by allowing basal metabolism to continue at low temperature levels (Colinet et al., Reference Colinet, Nguyen, Cloutier, Michaud and Hance2007; Alfaro-Tapia et al., Reference Alfaro-Tapia, Alvarez-Baca, Tougeron, Lavandero, Le Lann and Van Baaren2021). Reports have shown that reduction in BWC and subsequent increase in solute concentration may increase cold tolerance in insects (Worland, Reference Worland1996). In the current study there was no relationship between cold tolerance and BWC. This may be because insects in our assays did not experience repeated cold conditions that trigger any water loss and subsequent solute concentration increase. While Keosentse et al. (Reference Keosentse, Mutamiswa, Du Plessis and Nyamukondiwa2021) reported that BWC increased with larval stage in S. frugiperda, our results report otherwise on CTmin following repeated exposure. This may be because our present study measured BWC following plastic responses while Keosentse et al. (Reference Keosentse, Mutamiswa, Du Plessis and Nyamukondiwa2021) measured basal BWC. Given these responses, it indicates that S. frugiperda may trade-off basal BWC for plasticity of thermal tolerance.

Lipid content plays a vital role in cold tolerance as they can serve as anti-freezers in the insect haemolymph (Sinclair and Marshall, Reference Sinclair and Marshall2018; Trenti et al., Reference Trenti, Sandron, Guella and Lencioni2022). In winter, most insects do not feed and may face the unreplaced energy consumption, water loss and low temperatures (Sinclair et al., Reference Sinclair, Ferguson, Salehipour-Shirazi and MacMillan2013; Williams et al., Reference Williams, Henry and Sinclair2015). Low temperature is one of the stressors which affect neutral lipid fluidity and mobilization and energy drain, since lipids are the primary overwintering source of fuel (Sinclair and Marshall, Reference Sinclair and Marshall2018). As such, most overwintering insects end winter with fewer lipid stores than at the beginning (Sinclair, Reference Sinclair2015). For example, in laboratory-reared colonies of D. melanogaster, glycogen levels decreased following repeated cold exposure (Marshall and Sinclair, Reference Marshall and Sinclair2010). In addition, there was a positive correlation between BLC and cold tolerance in Drosophila spp. (Hoffmann et al., Reference Hoffmann, Hallas, Sinclair and Partridge2001; Kaczmarek and Boguś, Reference Kaczmarek and Boguś2021). However, in the current study, our results showed no significant correlation between BLC and cold tolerance in S. frugiperda. A recent study attributed glycerol as the key cryoprotectant used by S. frugiperda (Vatanparast and Park, Reference Vatanparast and Park2022). This therefore suggests that the influence of BLC on cold tolerance may be species dependent and glycerol maybe more important in this species.

In conclusion, the current study documents life-stage-related variation in cold tolerance for S. frugiperda following repeated thermal exposure. Our results suggest that repeated cold exposure differentially influences the fitness of S. frugiperda in nature where vulnerability is life-stage and trait dependent. In addition, the study provides evidence that cold hardening may be an important mechanism for S. frugiperda to cope with repeated cold exposure over the short term. These cold tolerance responses may provide temporal fitness benefits following repeated cold conditions in nature hence population persistence under changing environments. The results also have direct implications on the geographic distribution of the pest under climate change scenarios where warming winter seasons will lead to even further spatial expansion and multivoltinism due to favourable conditions. For a polyphagous pest such as S. frugiperda this will be critical as alternative hosts will support multiple generations enough to exert pest pressure on the main crop in the subsequent season (Vatanparast and Park, Reference Vatanparast and Park2022). In such cases, management practices should consider area-wide monitoring of the pest populations even during off-season for early integrated pest management practices. This may include improved phytosanitary measures and reduction of alternative hosts on-farm. More importantly, augmentative releases to boost parasitoid populations during this period will also be a feasible option to suppress the pest populations to reduce the pressure in the main crop in the impending season. This will greatly reduce pest pressure, but costs are associated with control of the outbreak pest using synthetic pesticides on-season. Future studies should therefore determine the intensity of such parasitoid levels to maintain pest pressure well below economic injury levels.

Acknowledgements

The authors are very grateful for the National Research Foundation (NRF) and SACTA NPC trust PhD bursaries to AM and the support from the University of the Free State and NRF to FC. The authors also appreciate support from Midlands State University and Rhodes University to RM. In addition, the authors acknowledge Tsabang Mashigo and Lugisani Mulaudzi for technical assistance. The authors are also grateful to Hannelene du Plessis for kindly providing the stock culture of the fall armyworm.

References

Alfaro-Tapia, A, Alvarez-Baca, JK, Tougeron, K, Lavandero, B, Le Lann, C and Van Baaren, J (2021) Overwintering strategies and life-history traits of different populations of Aphidius platensis along a latitudinal gradient in Chile. Entomologia Generalis 42, 127145.CrossRefGoogle Scholar
Andersen, JL, Manenti, T, Sørensen, JG, MacMillan, HA, Loeschcke, V and Overgaard, J (2015) How to assess Drosophila cold tolerance: chill coma temperature and lower lethal temperature are the best predictors of cold distribution limits. Functional Ecology 29, 5565.CrossRefGoogle Scholar
Andersen, MK, Folkersen, R, MacMillan, HA and Overgaard, J (2017) Cold acclimation improves chill tolerance in the migratory locust through preservation of ion balance and membrane potential. Journal of Experimental Biology 220, 487496.Google ScholarPubMed
Andreadis, SS and Athanassiou, CG (2017) A review of insect cold hardiness and its potential in stored product insect control. Crop Protection 91, 9399.CrossRefGoogle Scholar
Andrew, SC and Kemp, DJ (2016) Stress tolerance in a novel system: genetic and environmental sources of (co)variation for cold tolerance in the butterfly Eurema smilax. Austral Ecology 41, 529537.CrossRefGoogle Scholar
Avargues-Weber, A, Lihoreau, M, Isabel, G and Giurfa, M (2015) Information transfer beyond the waggle dance: observational learning in bees and flies. Frontiers in Ecology and Evolution 3, 24.Google Scholar
Bale, JS (2002) Insects and low temperatures: from molecular biology to distributions and abundance. Philosophical Transactions of the Royal Society of London, Series B: Biological Sciences 357, 849862.CrossRefGoogle ScholarPubMed
Bazinet, AL, Marshall, KE, Macmillan, HA, Williams, CM and Sinclair, BJ (2010) Rapid changes in desiccation resistance in Drosophila melanogaster are facilitated by changes in cuticular permeability. Journal of Insect Physiology 56, 20062012.CrossRefGoogle ScholarPubMed
Boake, CR (1989) Repeatability: its role in evolutionary studies of mating behavior. Evolutionary Ecology 3, 173182.CrossRefGoogle Scholar
Buckley, LB and Huey, RB (2016) How extreme temperatures impact organisms and the evolution of their thermal tolerance. Integrative and Comparative Biology 56, 98109.CrossRefGoogle ScholarPubMed
Chapman, JW, Williams, T, Escribano, A, Caballero, P, Cave, RD and Goulson, D (1999) Age-related cannibalism and horizontal transmission of a nuclear polyhedrosis virus in larval Spodoptera frugiperda. Ecological Entomology 24, 268275.CrossRefGoogle Scholar
Chidawanyika, F and Terblanche, JS (2011) Rapid thermal responses and thermal tolerance in adult codling moth Cydia pomonella (Lepidoptera: Tortricidae). Journal of Insect Physiology 57, 108117.CrossRefGoogle ScholarPubMed
Chidawanyika, F, Mudavanhu, P and Nyamukondiwa, C (2012) Biologically based methods for pest management in agriculture under changing climates: challenges and future directions. Insects 3, 11711189.CrossRefGoogle ScholarPubMed
Chidawanyika, F, Nyamukondiwa, C, Strathie, L and Fischer, K (2017) Effects of thermal regimes, starvation and age on heat tolerance of the parthenium beetle Zygogramma bicolorata (Coleoptera: Chrysomelidae) following dynamic and static protocols. PLoS ONE 12, e0169371.CrossRefGoogle ScholarPubMed
Chidawanyika, F, Chikowore, G and Mutamiswa, R (2020) Thermal tolerance of the biological control agent Neolema abbreviata and its potential geographic distribution together with its host Tradescantia fluminensis in South Africa. Biological Control 149, 104315.CrossRefGoogle Scholar
Chown, SL and Nicolson, SW (2004) Insect Physiological Ecology: Mechanisms and Patterns. Oxford, UK: Oxford University Press.CrossRefGoogle Scholar
Cock, MJ, Beseh, PK, Buddie, AG, Cafá, G and Crozier, J (2017) Molecular methods to detect Spodoptera frugiperda in Ghana, and implications for monitoring the spread of invasive species in developing countries. Scientific Reports 7, 4103.CrossRefGoogle ScholarPubMed
Colinet, H, Nguyen, TTA, Cloutier, C, Michaud, D and Hance, T (2007) Proteomic profiling of a parasitic wasp exposed to constant and fluctuating cold exposure. Insect Biochemistry and Molecular Biology 37, 11771188.CrossRefGoogle ScholarPubMed
Cox, J, Schubert, AM, Travisano, M and Putonti, C (2010) Adaptive evolution and inherent tolerance to extreme thermal environments. BMC Evolutionary Biology 10, 111.CrossRefGoogle ScholarPubMed
Day, R, Abrahams, P, Bateman, M, Beale, T, Clottey, V, Cock, M, Colmenarez, Y, Corniani, N, Early, R, Godwin, J and Gomez, J (2017) Fall armyworm: impacts and implications for Africa. Outlooks on Pest Management 28, 196201.CrossRefGoogle Scholar
Du Plessis, H, Schlemmer, ML and Van den Berg, J (2020) The effect of temperature on the development of Spodoptera frugiperda (Lepidoptera: Noctuidae). Insects 11, 228.CrossRefGoogle ScholarPubMed
Early, R, González-Moreno, P, Murphy, ST and Day, R (2018) Forecasting the global extent of invasion of the cereal pest Spodoptera frugiperda, the fall armyworm. NeoBiota 40, 2550.CrossRefGoogle Scholar
Elnitsky, MA, Hayward, SA, Rinehart, JP, Denlinger, DL and Lee, RE Jr (2008) Cryoprotective dehydration and the resistance to inoculative freezing in the Antarctic Midge, Belgica Antarctica. Journal of Experimental Biology 211, 524530.CrossRefGoogle ScholarPubMed
Feng, Y, Zhang, L, Li, W, Yang, X and Zong, S (2018) Cold hardiness of overwintering larvae of Sphenoptera sp. (Coleoptera: Buprestidae) in Western China. Journal of Economic Entomology 111, 247251.CrossRefGoogle ScholarPubMed
Goergen, G, Kumar, PL, Sankung, SB, Togola, A and Tamò, M (2016) First report of outbreaks of the fall armyworm Spodoptera frugiperda (JE Smith) (Lepidoptera, Noctuidae), a new alien invasive pest in West and Central Africa. PLoS ONE 11, e0165632.CrossRefGoogle Scholar
Gregory, PJ, Johnson, SN, Newton, AC and Ingram, JS (2009) Integrating pests and pathogens into the climate change/food security debate. Journal of Experimental Botany 60, 28272838.CrossRefGoogle ScholarPubMed
Grinder, RM, Bassar, RD and Auer, SK (2020) Upper thermal limits are repeatable in Trinidadian guppies. Journal of Thermal Biology 90, 102597.CrossRefGoogle ScholarPubMed
Hazell, SP and Bale, JS (2011) Low temperature thresholds: are chill coma and CTmin synonymous? Journal of Insect Physiology 57, 10851089.CrossRefGoogle ScholarPubMed
Hoffmann, AA, Hallas, R, Sinclair, C and Partridge, L (2001) Rapid loss of stress resistance in Drosophila melanogaster under adaptation to laboratory culture. Evolution 55, 436438.Google ScholarPubMed
Izadi, H, Mohammadzadeh, M and Mehrabian, M (2019) Cold tolerance of the Tribolium castaneum (Coleoptera: Tenebrionidae), under different thermal regimes: impact of cold acclimation. Journal of Economic Entomology 112, 19831988.CrossRefGoogle ScholarPubMed
Kaczmarek, A and Boguś, M (2021) The metabolism and role of free fatty acids in key physiological processes in insects of medical, veterinary and forensic importance. PeerJ 9, e12563.CrossRefGoogle Scholar
Kasoma, C, Shimelis, H and Laing, MD (2021) Fall armyworm invasion in Africa: implications for maize production and breeding. Journal of Crop Improvement 35, 111146.CrossRefGoogle Scholar
Kebede, M and Shimalis, T (2018) Out-break, distribution and management of fall armyworm, Spodoptera frugiperda JE Smith in Africa: the status and prospects. Academy of Agricultural Journal 3, 551568.Google Scholar
Keosentse, O, Mutamiswa, R, Du Plessis, H and Nyamukondiwa, C (2021) Developmental stage variation in Spodoptera frugiperda (Lepidoptera: Noctuidae) low temperature tolerance: implications for overwintering. Austral Entomology 60, 400410.CrossRefGoogle Scholar
Le Bourg, E (2007) Hormetic effects of repeated exposures to cold at young age on longevity, aging and resistance to heat or cold shocks in Drosophila melanogaster. Biogerontology 8, 431444.CrossRefGoogle ScholarPubMed
Lee, RE Jr. (2010) A primer on insect cold-tolerance. In Denlinger, DL and Lee, RE (eds), Insect Low Temperature Biology New York: Cambridge University Press, pp. 334.CrossRefGoogle Scholar
Lee, RE Jr, Chen, C-P and Denlinger, DL (1987) A rapid cold-hardening process in insects. Science (New York, N.Y.) 238, 14151417.CrossRefGoogle ScholarPubMed
Leroi, AM, Bennett, AF and Lenski, RE (1994) Temperature acclimation and competitive fitness: an experimental test of the beneficial acclimation assumption. Proceedings of the National Academy of Sciences 91, 19171921.CrossRefGoogle ScholarPubMed
Lu, Y and Adang, MJ (1996) Distinguishing fall armyworm (Lepidoptera: Noctuidae) strains using a diagnostic mitochondrial DNA marker. Florida Entomologist 79, 4855.CrossRefGoogle Scholar
Lynch, HJ, Rhainds, M, Calabrese, JM, Cantrell, S, Cosner, C and Fagan, WF (2014) How climate extremes not means define a species' geographic range boundary via a demographic tipping point. Ecological Monographs 84, 131149.CrossRefGoogle Scholar
Marshall, KE and Sinclair, BJ (2010) Repeated stress exposure results in a survival–reproduction trade-off in Drosophila melanogaster. Proceedings of the Royal Society B: Biological Sciences 277, 963969.CrossRefGoogle Scholar
Marshall, KE and Sinclair, BJ (2012) The impacts of repeated cold exposure on insects. Journal of Experimental Biology 215, 16071613.CrossRefGoogle ScholarPubMed
Milton, CC and Partridge, L (2008) Brief carbon dioxide exposure blocks heat hardening but not cold acclimation in Drosophila melanogaster. Journal of Insect Physiology 54, 3240.CrossRefGoogle Scholar
Mitchell, KA, Boardman, L, Clusella-Trullas, S and Terblanche, JS (2017) Effects of nutrient and water restriction on thermal tolerance: a test of mechanisms and hypotheses. Comparative Biochemistry and Physiology, Part A: Molecular & Integrative Physiology 212, 1523.CrossRefGoogle ScholarPubMed
Morgan, R, Finnøen, MH and Jutfelt, F (2018) CTmax is repeatable and doesn't reduce growth in zebrafish. Scientific Reports 8, 18.CrossRefGoogle ScholarPubMed
Mutamiswa, R, Machekano, H, Chidawanyika, F and Nyamukondiwa, C (2018) Thermal resilience may shape population abundance of two sympatric congeneric Cotesia species (Hymenoptera: Braconidae). PLoS ONE 13, e0191840.CrossRefGoogle ScholarPubMed
Mutamiswa, R, Machekano, H, Chidawanyika, F and Nyamukondiwa, C (2019) Life-stage related responses to combined effects of acclimation temperature and humidity on the thermal tolerance of Chilo partellus (Swinhoe) (Lepidoptera: Crambidae). Journal of Thermal Biology 79, 8594.CrossRefGoogle ScholarPubMed
Näslund, J (2021) Behavioural repeatability in larval Limnephilus lunatus Curtis, 1834 (Trichoptera) in an open-field test. Aquatic Insects 42, 6277.CrossRefGoogle Scholar
Nboyine, JA, Kusi, F, Abudulai, M, Badii, BK, Zakaria, M, Adu, GB, Haruna, A, Seidu, A, Osei, V, Alhassan, S and Yahaya, A (2020) A new pest, Spodoptera frugiperda (JE Smith), in tropical Africa: Its seasonal dynamics and damage in maize fields in northern Ghana. Crop Protection 127, 104960.CrossRefGoogle Scholar
Neal, AS, Diaz, R, Qureshi, JA and Cave, RD (2021) Adult cold tolerance and potential North American distribution of Myllocerus undecimpustulatus undatus (Coleoptera: Curculionidae). Biological Invasions 23, 37193731.CrossRefGoogle Scholar
Niemelä, PT and Dingemanse, NJ (2017) Individual versus pseudo-repeatability in behaviour: lessons from translocation experiments in a wild insect. Journal of Animal Ecology 86, 10331043.CrossRefGoogle Scholar
Nyamukondiwa, C and Terblanche, JS (2009) Thermal tolerance in adult Mediterranean and Natal fruit flies (Ceratitis capitata and Ceratitis rosa): effects of age, gender and feeding status. Journal of Thermal Biology 34, 406414.CrossRefGoogle Scholar
Nyamukondiwa, C, Chidawanyika, F, Machekano, H, Mutamiswa, R, Sands, B, Mgidiswa, N and Wall, R (2018) Climate variability differentially impacts thermal fitness traits in three Coprophagic beetle species. PLoS ONE 13, e0198610.CrossRefGoogle ScholarPubMed
Nyamukondiwa, C, Machekano, H, Chidawanyika, F, Mutamiswa, R, Ma, G and Ma, CS (2022) Geographic dispersion of invasive crop pests: the role of basal, plastic climate stress tolerance and other complementary traits in the tropics. Current Opinion in Insect Science 50, 100878.CrossRefGoogle ScholarPubMed
O'Donnell, MJ, Regish, AM, McCormick, SD and Letcher, BH (2020) How repeatable is CTmax within individual brook trout over short- and long-time intervals? Journal of Thermal Biology 89, 102559.CrossRefGoogle Scholar
O'Neill, E, Davis, HE and MacMillan, HA (2021) A lack of repeatability creates the illusion of a trade-off between basal and plastic cold tolerance. Proceedings of the Royal Society B 288, 20212121.CrossRefGoogle ScholarPubMed
Phophi, MM, Mafongoya, P and Lottering, S (2020) Perceptions of climate change and drivers of insect pest outbreaks in vegetable crops in Limpopo province of South Africa. Climate 8, 27.CrossRefGoogle Scholar
Prasanna, BM, Huesing, JE, Peschke, Eddy R (2018) Fall armyworm in Africa: A Guide for Integrated Pest Management, 1st edition. Mexico, CDMX: CIMMYT.Google Scholar
R Core Team (2021) R: A language and environment for statistical computing. R Foundation for Statistical Computing. https://www.r-project.org/.Google Scholar
Renault, D, Nedved, O, Hervant, F and Vernon, P (2004) The importance of fluctuating thermal regimes for repairing chill injuries in the tropical beetle Alphitobius diaperinus (Coleoptera: Tenebrionidae) during exposure to low temperature. Physiological Entomology 29, 139145.CrossRefGoogle Scholar
Sinclair, BJ (2015) Linking energetics and overwintering in temperate insects. Journal of Thermal Biology 54, 511.CrossRefGoogle ScholarPubMed
Sinclair, BJ and Marshall, KE (2018) The many roles of fats in overwintering insects. Journal of Experimental Biology 221, jeb161836.CrossRefGoogle ScholarPubMed
Sinclair, BJ and Marshall, KE (2018) The many roles of fats in overwintering insects. Journal of Experimental Biology 221, jeb161836. doi: 10.1242/jeb.161836.CrossRefGoogle ScholarPubMed
Sinclair, BJ, Ferguson, LV, Salehipour-Shirazi, G and MacMillan, HA (2013) Cross-tolerance and cross-talk in the cold: relating low temperatures to desiccation and immune stress in insects. Integrative and Comparative Biology 53, 545556.CrossRefGoogle ScholarPubMed
Sinclair, BJ, Alvarado, LEC and Ferguson, LV (2015) An invitation to measure insect cold tolerance: methods, approaches, and workflow. Journal of Thermal Biology 53, 180197.CrossRefGoogle ScholarPubMed
Storey, KB and Storey, JM (2012) Insect cold hardiness: metabolic, gene, and protein adaptation. Canadian Journal of Zoology 90, 456475.CrossRefGoogle Scholar
Tarusikirwa, VL, Mutamiswa, R, Chidawanyika, F and Nyamukondiwa, C (2020) Cold hardiness of the South American tomato pinworm Tuta absoluta (Lepidoptera: Gelechiidae): both larvae and adults are chill-susceptible. Pest Management Science 77, 184193.CrossRefGoogle ScholarPubMed
Teets, NM and Denlinger, DL (2013) Physiological mechanisms of seasonal and rapid cold hardening in insects. Physiological Entomology 38, 105116.CrossRefGoogle Scholar
Terblanche, JS, Hoffmann, AA, Mitchell, KA, Rako, L, le Roux, PC and Chown, SL (2011) Ecologically relevant measures of tolerance to potentially lethal temperatures. Journal of Experimental Biology 214, 37133725.CrossRefGoogle ScholarPubMed
Tollefson, J (2014) The case of the missing heat. Nature 505, 276278.CrossRefGoogle ScholarPubMed
Toxopeus, J, Koštál, V and Sinclair, BJ (2019) Evidence for non-colligative function of small cryoprotectants in a freeze-tolerant insect. Proceedings of the Royal Society B 286, 20190050.CrossRefGoogle Scholar
Travis, WR (2014) Weather and climate extremes: pacemakers of adaptation? Weather and Climate Extremes 5, 2939.CrossRefGoogle Scholar
Trenti, F, Sandron, T, Guella, G and Lencioni, V (2022) Insect cold tolerance and lipidome: membrane lipid composition of two chironomid species differently adapted to cold. Cryobiology 106, 8490.CrossRefGoogle ScholarPubMed
van Dooremalen, C, Suring, W and Ellers, J (2011) Fatty acid composition and extreme temperature tolerance following exposure to fluctuating temperatures in a soil arthropod. Journal of Insect Physiology 57, 12671273.CrossRefGoogle Scholar
Vatanparast, M and Park, Y (2022) Cold tolerance strategies of the fall armyworm, Spodoptera frugiperda (Smith) (Lepidoptera: Noctuidae). Science Reports 12, 116.Google ScholarPubMed
Weldon, CW, Nyamukondiwa, C, Karsten, M, Chown, SL and Terblanche, JS (2018) Geographic variation and plasticity in climate stress resistance among southern African populations of Ceratitis capitata (Wiedemann)(Diptera: Tephritidae). Scientific Reports 8, 9849.CrossRefGoogle ScholarPubMed
Williams, CM, Henry, HA and Sinclair, BJ (2015) Cold truths: how winter drives responses of terrestrial organisms to climate change. Biological Reviews 90, 214235.CrossRefGoogle ScholarPubMed
Worland, MR (1996) The relationship between water content and cold tolerance in the Arctic collembolan Onychiurus arcticus (Collembola: Onychiuridae). European Journal of Entomology 93, 341348.Google Scholar
Figure 0

Figure 1. CTmin in adult (virgin male and female) and larval stages of S. frugiperda following repeated cold exposure. Data points represent means of n = 20 while error bars denote 95% confidence limits for each gender and life stage. Different letters above error bars denote significant differences.

Figure 1

Figure 2. CCRT in adult (virgin male and female) and larval stages of S. frugiperda following repeated cold exposure. Data points represent means of n = 20 while error bars denote 95% confidence limits for each gender and life stage. Different letters above error bars denote significant differences.

Figure 2

Figure 3. BWC (g) across different life stages (A) and relationship between BWC and CTmin (B) in S. frugiperda.

Figure 3

Figure 4. BLC (g) across different life stages (A) and the relationship between BLC and CTmin (B) in S. frugiperda.