Abstract
When exposed to harsh environmental conditions, such as food scarcity and/or low temperature, Drosophila melanogaster females enter reproductive dormancy, a metabolic state that enhances stress resistance for survival at the expense of reproduction. Although the absence of egg chambers carrying yolk from the ovary has been used to define reproductive dormancy in this species, this definition is susceptible to false judgements of dormancy events: e.g. a trace amount of yolk could escape visual detection; a fly is judged to be in the non-dormancy state if it has a single yolk-containing egg chamber even when other egg chambers are devoid of yolk. In this study, we propose an alternative method for describing the maturation state of oocytes, in which the amount of yolk in the entire ovary is quantified by the fluorescence intensity derived from GFP, which is expressed as a fusion with the major yolk protein Yp1. We show that yolk deposition increases with temperature with a sigmoidal function, and the quality of food substantially alters the maximum accumulation of yolk attainable at a given temperature. The Yp1::GFP reporter will serve as a reliable tool for quantifying the amount of yolk and provides a new means for defining the dormancy state in D. melanogaster.
Highlights
Many insects inhabiting the temperate zone overwinter by minimising metabolism and enhancing stress tolerance for survival under harsh environmental conditions
We demonstrated that yolk protein 1 (Yp1) as a major constituent of yolk serves as a useful marker of the amount of yolk in an oocyte and in a whole ovary, which is detected by a GFP-tag attached to Yp1 and quantified by the GFP fluorescence intensity
With the aid of Yp1::GFP, we demonstrated that the feeding state and temperature, which affect dormancy in D. melanogaster (Ojima et al, 2018), strongly impacted yolk accumulation in the ovary, yet the stimulus–response dynamics revealed a range of varieties of stress responsiveness among individuals
Summary
Many insects inhabiting the temperate zone overwinter by minimising metabolism and enhancing stress tolerance for survival under harsh environmental conditions. This specialised state enabling an organism to surpass unfavourable climate is known as diapause (Ragland et al, 2019; Saunders, 2020). Insects enter diapause well before the onset of extreme cold weather, often in response to anticipatory external cues, such as a short photoperiod and lower temperature; some species undergo obligatory diapause irrespective of environmental conditions (Denlinger, 2002; Beer and Helfrich-Förster, 2020; Saunders, 2020). Several diapause studies in Drosophila showed that some of the natural populations in higher latitudes exhibit a greater tendency to undergo reproductive arrest under low temperature and/or a short photoperiod; alleles in the genes PI3 kinase (Williams et al, 2006), timeless (Tauber et al, 2007) and couch potato (cpo; Schmidt et al, 2008, see Lee et al, 2011) were implicated in these phenotypic variations
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