Symbiotic nutrient cycling enables the long-term survival of Aiptasia in the absence of heterotrophic food sources

Nils Rädecker, Anders Meibom
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Abstract

Phototrophic Cnidaria are mixotrophic organisms that can complement their heterotrophic diet with nutrients assimilated by their algal endosymbionts. Metabolic models suggest that the translocation of photosynthates and their derivatives from the algae may be sufficient to cover the metabolic energy demands of the host. However, the importance of heterotrophy to the nutritional budget of these holobionts remains unclear. Here, we report on the long-term survival of the photosymbiotic anemone Aiptasia in the absence of heterotrophic food sources. Following one year of heterotrophic starvation, these anemones remained fully viable but showed an 85 % reduction in biomass compared to their regularly fed counterparts. This shrinking was accompanied by a reduction in host protein content and algal density, indicative of severe nitrogen limitation. Nonetheless, isotopic labeling experiments combined with NanoSIMS imaging revealed that the contribution of algal-derived nutrients to the host metabolism remained unaffected due to an increase in algal photosynthesis and more efficient carbon translocation. Taken together, our results suggest that, on a one- year timescale, heterotrophic feeding is not essential to fulfilling the energy requirements of the holobiont. But, while symbiotic nutrient cycling effectively retains carbon in the holobiont over long time scales, our data suggest that heterotrophic feeding is a critical source of nitrogen required for holobiont growth under oligotrophic conditions.
共生营养循环使无异养食物来源的无食动物能够长期生存
光养刺胞菌是一种混合营养生物,可以用藻类内共生体吸收的营养补充其异养饮食。代谢模型表明,藻类的光合产物及其衍生物的转运可能足以满足宿主的代谢能量需求。然而,异养对这些全息生物营养预算的重要性仍不清楚。在这里,我们报告了光共生海葵在缺乏异养食物来源的情况下的长期生存。经过一年的异养饥饿,这些海葵仍然可以完全存活,但与定期喂食的海葵相比,生物量减少了85%。这种萎缩伴随着宿主蛋白质含量和藻类密度的减少,表明严重的氮限制。尽管如此,同位素标记实验结合NanoSIMS成像显示,由于藻类光合作用的增加和更有效的碳转运,藻类来源的营养物质对宿主代谢的贡献没有受到影响。综上所述,我们的研究结果表明,在一年的时间尺度上,异养喂养对于满足全息生物的能量需求并不是必不可少的。但是,虽然共生营养循环在长时间尺度上有效地保留了全息生物中的碳,但我们的数据表明,异养饲养是在寡营养条件下全息生物生长所需氮的关键来源。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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