Abstract
Diapause, a programmed developmental arrest primarily induced by seasonal environmental changes, is very common in the animal kingdom, and found in vertebrates and invertebrates alike. Diapause provides an adaptive advantage to animals, as it increases the odds of surviving adverse conditions. In insects, individuals perceive photoperiodic cues and modify endocrine signaling to direct reproductive diapause traits, such as ovary arrest and increased fat accumulation. However, it remains unclear as to which endocrine factors are involved in this process and how they regulate the onset of reproductive diapause. Here, we found that the long day-mediated drop in the concentration of the steroid hormone ecdysone is essential for the preparation of photoperiodic reproductive diapause in Colaphellus bowringi, an economically important cabbage beetle. The diapause-inducing long-day condition reduced the expression of ecdysone biosynthetic genes, explaining the drop in the titer of 20-hydroxyecdysone (20E, the active form of ecdysone) in female adults. Application of exogenous 20E induced vitellogenesis and ovarian development but reduced fat accumulation in the diapause-destined females. Knocking down the ecdysone receptor (EcR) in females destined for reproduction blocked reproductive development and induced diapause traits. RNA-seq and hormone measurements indicated that 20E stimulates the production of juvenile hormone (JH), a key endocrine factor in reproductive diapause. To verify this, we depleted three ecdysone biosynthetic enzymes via RNAi, which confirmed that 20E is critical for JH biosynthesis and reproductive diapause. Importantly, impairing Met function, a component of the JH intracellular receptor, partially blocked the 20E-regulated reproductive diapause preparation, indicating that 20E regulates reproductive diapause in both JH-dependent and -independent manners. Finally, we found that 20E deficiency decreased ecdysis-triggering hormone signaling and reduced JH production, thereby inducing diapause. Together, these results suggest that 20E signaling is a pivotal regulator that coordinates reproductive plasticity in response to environmental inputs.
Highlights
Under suboptimal conditions, many organisms, including nematodes, crustaceans, insects, fish and even mammals, can extend their lifespan and survive through diapause, a plastic and adaptive process that is a form of dormancy [1, 2]
Developmental arrest pervades organismal development and physiology where it facilitates an enormous range of adaptive responses to stressful conditions
Endocrine signals play a central role in translating environmental cues such as photoperiod into reproductive diapause-related physiology and behavior
Summary
Many organisms, including nematodes, crustaceans, insects, fish and even mammals, can extend their lifespan and survive through diapause, a plastic and adaptive process that is a form of dormancy [1, 2]. Individuals undergoing diapause generally exhibit substantial fat accumulation, reduced metabolism, slowed aging, and enhanced tolerance to adverse conditions [1]. Animals capable of entering diapause can be employed in dissecting mechanisms of obesity, metabolic regulation, and longevity [3,4,5,6]. Insects are the most numerous and diverse group of animals. Considering their significant importance on agricultural production and human health, and the advantage of convenient genetic manipulations, insects can serve as the excellent models in the study of diapause [7]
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