Kamar Nayal, Joshua J Krupp, Osama H M H Abdalla, Joel D Levine
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Although increased transpiration - resulting from the loss of the oenocytes and HCs - was hypothesized to be responsible for the decrease in desiccation survival, this possibility was not directly tested. Here we investigate the underlying physiological mechanisms contributing to the reduced survival of oenocyte-less (oe-) flies. Using flow-through respirometry we show that oe- flies, regardless of sex, exhibited an increased rate of transpiration relative to wild-type controls, and that coating oe- flies with fly-derived HC extract restored the rate to near wild-type levels. Importantly, total body water stores, including metabolic water reserves, as well as dehydration tolerance, measured as the percent of total body water lost at time of death, were largely unchanged in oe- flies. 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引用次数: 0
摘要
干燥是所有陆生生物,尤其是昆虫面临的一个基本挑战。昆虫的体型相对较小,表面积与体积的比例较大,很容易受到快速蒸发失水和脱水的影响。为了应对这些物理限制,昆虫获得了专门的适应性,包括疏水性角质层,作为蒸腾的物理屏障。我们以前曾报道过,在干燥条件下,果蝇(Drosophila melanogaster)的存活率会显著降低。尽管有人推测蒸腾作用的增加--由于失去了卵母细胞和 HCs--是干燥存活率降低的原因,但这种可能性并未得到直接验证。在这里,我们研究了导致无卵母细胞(oe-)苍蝇存活率降低的潜在生理机制。通过流式呼吸测定法,我们发现与野生型对照组相比,无卵母细胞苍蝇(无论性别)的蒸腾速率都有所提高,给无卵母细胞苍蝇涂上苍蝇提取的 HC 提取物后,蒸腾速率恢复到接近野生型的水平。重要的是,包括代谢水储备在内的体内总蓄水量以及脱水耐受性(以死亡时体内总失水量的百分比来衡量)在黑蝇体内基本没有变化。总之,我们的研究结果直接证明了卵母细胞和角质层碳氢化合物在促进脱水抵抗力方面发挥着极其重要的作用。
Cuticular hydrocarbons promote desiccation resistance by preventing transpiration in D. melanogaster.
Desiccation is a fundamental challenge confronted by all terrestrial organisms, particularly insects. With a relatively small body size and large surface-to-volume ratio insects are susceptible to rapid evaporative water loss and dehydration. To counter these physical constraints, insects have acquired specialized adaptations, including a hydrophobic cuticle that acts as a physical barrier to transpiration. We previously reported that genetic ablation of the oenocytes - specialized cells required to produce cuticular hydrocarbons (HCs) - significantly reduced survivorship under desiccative conditions in the fruit fly, Drosophila melanogaster. Although increased transpiration - resulting from the loss of the oenocytes and HCs - was hypothesized to be responsible for the decrease in desiccation survival, this possibility was not directly tested. Here we investigate the underlying physiological mechanisms contributing to the reduced survival of oenocyte-less (oe-) flies. Using flow-through respirometry we show that oe- flies, regardless of sex, exhibited an increased rate of transpiration relative to wild-type controls, and that coating oe- flies with fly-derived HC extract restored the rate to near wild-type levels. Importantly, total body water stores, including metabolic water reserves, as well as dehydration tolerance, measured as the percent of total body water lost at time of death, were largely unchanged in oe- flies. Together, our results directly demonstrate the critically important role played by the oenocytes and cuticular HCs to promote desiccation resistance.
期刊介绍:
Journal of Experimental Biology is the leading primary research journal in comparative physiology and publishes papers on the form and function of living organisms at all levels of biological organisation, from the molecular and subcellular to the integrated whole animal.