Integrative omics approaches reveal mechanisms of combined heat stress and extreme hypoxia tolerance in a Cerambycid beetle larva

Atmospheric oxygen, which is essential for energy metabolism, can directly influence an animal's heat tolerance by affecting oxygen transport processes, especially in those living in oxygen-poor environments, such as plant tissues, underground or aquatic environments. Yet, the interplay of oxygen and temperature are rarely studied together, limiting our ability to predict their combined effects on insect performance. This study examines the tolerance of a large xylophagous cerambycid beetle Cacosceles newmannii to combined hypoxic and thermal stress using performance assays (duration of righting response) coupled with transcriptomic and metabolomic analyses. Metabolomic profiling showed that most metabolites were downregulated in the body but upregulated in the haemolymph as stress increased. Transcriptomic profiles clustered primarily by temperature (25 °C vs 35 °C), independent of oxygen level. Cacosceles newmannii appears capable of modulating its performance to reduce the energy costs and physiological damage induced by hypoxia. This suggested a high baseline hypoxia tolerance rather than a rapid plastic (induced) physiological hypoxia response, probably due to the species' endophytic lifestyle. Conversely, thermal stress led to a predictable increase in metabolic activity but did not markedly affect performance, triggering adjustments to maintain cellular functions while limiting the impact of stresses expected under conditions of high temperature, such as desiccation. In short, our study highlights the distinct metabolic pathways mobilised to cope with hypoxic versus thermal stress, emphasizing the importance of integrated approaches in understanding insect responses to environmental changes. These findings have significant implications for understanding the species' ecology, with applications for pest management and sustainable agriculture in the context of climate change.