Gözde Güney , Doga Cedden , Johannes Körnig , Bernd Ulber , Franziska Beran , Stefan Scholten , Michael Rostás
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引用次数: 0
Abstract
Aestivation is a form of seasonal dormancy observed in various insect species, usually coinciding with the summer season. The cabbage stem flea beetle, Psylliodes chrysocephala (Coleoptera: Chrysomelidae), is a key pest of oilseed rape that obligatorily aestivates as adult in late summer. Since the physiological and transcriptional processes linked to aestivation in P. chrysocephala are still little understood, we analyzed relevant physiological parameters and performed RNA-seq analyses on laboratory-reared beetles in their pre-aestivation, aestivation, and post-aestivation stages. We found that the beetles reached aestivation at 15 days post-eclosion, showing strongly reduced metabolic activity, with less than 50% CO2 production, compared to pre-aestivating individuals. Under constant laboratory conditions, the beetles aestivated for about 25 days. Female beetles reached reproductive maturity at a median of 52 days post-eclosion. Furthermore, aestivating beetles had significantly reduced carbohydrate reserves and increased lipid reserves compared with pre-aestivating beetles, indicating that aestivation is associated with drastic changes in energy metabolism. Aestivating beetles contained 30% less water and their survival rates under high-temperature conditions (30 °C) were 40% higher compared to pre-aestivating beetles. RNA-seq studies showed that, in particular, gene ontology terms related to carbohydrate and lipid metabolism, digestion, and mitochondrial activity were enriched, with clear differences in transcript abundance between beetles in aestivation compared to pre- or post-aestivation. Specifically, mitochondrial transcripts, such as respiratory chain I subunits, and digestion-related transcripts, such as trypsin, were less abundant during aestivation, which supports the idea that aestivation is associated with decreased metabolic activity. This study represents the first exploration of the transcriptomic and physiological processes linked to aestivation in P. chrysocephala.
休眠是各种昆虫的一种季节性休眠形式,通常与夏季相吻合。卷心菜茎跳甲(鞘翅目:蝶形目)是油菜的主要害虫,成虫必须在夏末休眠。由于对 P. chrysocephala 惊蛰相关的生理和转录过程了解甚少,我们分析了相关的生理参数,并对实验室饲养的处于惊蛰前、惊蛰期和惊蛰后阶段的甲虫进行了 RNA-seq 分析。我们发现,甲虫在惊蛰后15天达到惊蛰期,与惊蛰前的个体相比,新陈代谢活动大大降低,二氧化碳产生量不足50%。在恒定的实验室条件下,甲虫的休眠期约为25天。雌甲虫在爆发后中位数为52天时达到生殖成熟。此外,与动情前相比,动情甲虫的碳水化合物储备明显减少,而脂质储备增加,这表明动情与能量代谢的急剧变化有关。与动情前甲虫相比,动情甲虫的含水量减少了30%,它们在高温条件下(30 °C)的存活率提高了40%。RNA-seq研究表明,与碳水化合物和脂质代谢、消化和线粒体活动相关的基因本体术语特别丰富,与休眠前或休眠后相比,休眠期甲虫的转录本丰度有明显差异。具体来说,线粒体转录本(如呼吸链 I 亚基)和消化相关转录本(如胰蛋白酶)在动情期的丰度较低,这支持了动情期与代谢活动减少有关的观点。这项研究首次探索了与金龟子休眠相关的转录组和生理过程。
期刊介绍:
This international journal publishes original contributions and mini-reviews in the fields of insect biochemistry and insect molecular biology. Main areas of interest are neurochemistry, hormone and pheromone biochemistry, enzymes and metabolism, hormone action and gene regulation, gene characterization and structure, pharmacology, immunology and cell and tissue culture. Papers on the biochemistry and molecular biology of other groups of arthropods are published if of general interest to the readership. Technique papers will be considered for publication if they significantly advance the field of insect biochemistry and molecular biology in the opinion of the Editors and Editorial Board.