Physiological Metabolic Responses of Ophraella communa to High Temperature Stress

Chen, Hongsong; Solangi, Ghulam Sarwar; Zhao, Chenchen; Liu, Yang; Guo, Jianying; FangHao, Wan; Zhou, Zhongshi

doi:10.3389/fphys.2019.01053

Cited by 13 publications

(6 citation statements)

References 96 publications

(156 reference statements)

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“…For example, direct effects may impact their physiology, behaviour, and life‐history traits, whereas indirect effects, mediated by host‐plant responses, may result in changes in their morphology, biochemistry, physiology, and abundance (Bale et al, 2002; Kazakis et al, 2007; Karthik et al, 2021). Due to the complexity of their life cycles, different developmental stages of insect herbivores can seasonally encounter different environmental conditions and also occupy different microhabitats resulting in exposure to different environmental stressors (Chen et al, 2019). As a result, the effects of environmental stressors depend on the developmental stages that experience them.…”

Section: Introductionmentioning

confidence: 99%

Life‐stage‐related desiccation and starvation resistance in the biological control agent Neolema abbreviata

Mulaudzi

Mutamiswa

Zachariades

et al. 2022

Entomologia Exp Applicata

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Climate variability in the tropics is partly associated with reduced and erratic precipitation, heat waves, and cold snaps thereby exerting abiotic environmental stressors to various arthropod species. For herbivorous insects, such extreme weather events may affect host plant quality and availability resulting in additional stressors such as desiccation and starvation. Neolema abbreviata Larcordaire (Coleoptera: Chrysomelidae) is a key biocontrol agent of Tradescantia fluminensis Vell. (Commelinaceae) and has recently been introduced in South Africa for management of its invasive host plant.However, it remains unknown how environmental stressors may influence its performance under anthropogenic climate change. Here, we investigated the effects of desiccation and starvation on performance of N. abbreviata larvae and adults and implications on biological control. Specifically, we measured desiccation and starvation resistance and critical thermal minima (CT min ) and maxima (CT max ) following stress. Desiccation and starvation pre-treatment reduced both low (CT min ) and high (CT max ) temperature tolerance in both life stages albeit larvae were less cold tolerant and more heat tolerant than adults. In addition, resistance decreased with duration of exposure with desiccation resistance being higher in larvae than in adults, whereas the converse was true for starvation resistance. This indicates the challenges N. abbreviata may encounter when it faces environmental stressors in nature. Therefore, with projected climate change, this may potentially impact on its field establishment, spread, and effectiveness, thereby negatively influencing future classical biocontrol programs. Overall, the results provide valuable information in modelling potential distribution of N. abbreviata and developing sustainable management options of T. fluminensis under rapidly changing environments.

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Section: Introductionmentioning

confidence: 99%

Life‐stage‐related desiccation and starvation resistance in the biological control agent Neolema abbreviata

Mulaudzi

Mutamiswa

Zachariades

et al. 2022

Entomologia Exp Applicata

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“…An increase in glucose was also seen in the haemolymph of Mytilus edulis to meet increased tissue energy demands in response to temperature stress [ 28 ]. The accumulation of sugars may also help to stabilise proteins against heat stress [ 29 ] and support the biosynthesis of defensive compounds induced by stress [ 30 ]. Additionally, sugar metabolites are capable of inducing antioxidant activity against oxidative stress [ 31 ].…”

Section: Resultsmentioning

confidence: 99%

Metabolite Changes of Perna canaliculus Following a Laboratory Marine Heatwave Exposure: Insights from Metabolomic Analyses

et al. 2023

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Temperature is considered to be a major abiotic factor influencing aquatic life. Marine heatwaves are emerging as threats to sustainable shellfish aquaculture, affecting the farming of New Zealand’s green-lipped mussel [Perna canaliculus (Gmelin, 1791)]. In this study, P. canaliculus were gradually exposed to high-temperature stress, mimicking a five-day marine heatwave event, to better understand the effects of heat stress on the metabolome of mussels. Following liquid chromatography-tandem mass spectrometry analyses of haemolymph samples, key sugar-based metabolites supported energy production via the glycolysis pathway and TCA cycle by 24 h and 48 h of heat stress. Anaerobic metabolism also fulfilled the role of energy production. Antioxidant molecules acted within thermally stressed mussels to mitigate oxidative stress. Purine metabolism supported tissue protection and energy replenishment. Pyrimidine metabolism supported the protection of nucleic acids and protein synthesis. Amino acids ensured balanced intracellular osmolality at 24 h and ammonia detoxification at 48 h. Altogether, this work provides evidence that P. canaliculus has the potential to adapt to heat stress up to 24 °C by regulating its energy metabolism, balancing nucleotide production, and implementing oxidative stress mechanisms over time. The data reported herein can also be used to evaluate the risks of heatwaves and improve mitigation strategies for aquaculture.

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“…Indeed, Drosophila melanogaster exposed to high temperatures during development had a long‐term reduction in fat storage due in part to apoptosis, even in flies exposed only to transient thermal stress (Klepsatel et al, 2016). Developmental delay could be caused by the buildup of these stress‐induced free radicals or heat‐induced energy depletion (Chen et al, 2019; Malmendal et al, 2006). Such buildup may partially explain the higher mortality and slower development we observed in larvae exposed to the highest temperature heatwaves (Apirajkamol et al, 2020; Kingsolver et al, 2021).…”

Section: Discussionmentioning

confidence: 99%

Heatwaves increase larval mortality and delay development of a solitary bee

Melone,

Stuligross,

Williams

2024

Ecological Entomology

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Heatwaves are expected to increase in frequency, intensity and duration due to climate change. For organisms like insects with discrete development, sensitivity may differ among life stages. Thermal sensitivity is of particular concern for species like bees that provide critical ecosystem services. Although social bees moderate nest temperatures through worker behaviour, solitary bees do not thermoregulate their nests, making immobile developing offspring especially vulnerable to such extreme events. We studied the effects of heatwaves on larval development in the solitary bee, Osmia lignaria, an important orchard pollinator and model species for solitary bee biology. We used a factorial design to assess the impacts of heatwave temperature and duration on larval mortality and development rate. Larvae were exposed to heatwaves under realistic diel temperature regimes, with daytime maxima of 31 or 37°C for 4 or 7 days at the beginning of development. Heatwave temperature strongly affected larval mortality. Exposure to 37°C heatwaves increased larval mortality by 130%, but the cooler 31°C heatwaves did not significantly impact mortality. Heatwave duration did not impact larval mortality. Larval development time also was affected by heatwave exposure. Compared with the no‐heatwave‐control, bees in the 31°C heatwave developed faster, and bees in the 37°C heatwave developed slower. Our study reveals the importance of stage‐specific effects of extreme events and suggests that the timing and maximum temperature of projected heatwaves may be more detrimental to populations than heatwave duration.

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Physiological Metabolic Responses of Ophraella communa to High Temperature Stress

Cited by 13 publications

References 96 publications

Life‐stage‐related desiccation and starvation resistance in the biological control agent Neolema abbreviata

Life‐stage‐related desiccation and starvation resistance in the biological control agent Neolema abbreviata

Metabolite Changes of Perna canaliculus Following a Laboratory Marine Heatwave Exposure: Insights from Metabolomic Analyses

Heatwaves increase larval mortality and delay development of a solitary bee

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