Biomolecular profiles of Arctic Sea-ice diatoms highlight the role of under-ice light in cellular energy allocation

IF 5.1 Q1 ECOLOGY ISME communications Pub Date : 2024-01-10 DOI:10.1093/ismeco/ycad010
Rebecca J Duncan, Daniel Nielsen, J. Søreide, Øystein Varpe, Mark J Tobin, Vanessa Pitusi, Philip Heraud, K. Petrou
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Abstract

Arctic sea-ice diatoms fuel polar marine food webs as they emerge from winter darkness into Spring. Through their photosynthetic activity they manufacture the nutrients and energy that underpin secondary production. Sea-ice diatom abundance and biomolecular composition vary in space and time. With climate change causing short-term extremes and long-term shifts in mean environmental conditions, understanding how and in what way diatoms adjust biomolecular stores with environmental perturbation is important to gain insight into future ecosystem energy production and nutrient transfer. Using synchrotron-based Fourier Transform Infra-Red microspectroscopy, we examined the biomolecular composition of five dominant sea-ice diatom taxa from landfast ice communities covering a range of under-ice light conditions during Spring, in Svalbard, Norway. In all five taxa we saw a doubling of lipid and fatty acid content when light transmitted to the ice-water interface was >5% but <15% (85–95% attenuation through snow and ice). We determined a threshold around 15% light transmittance after which biomolecular synthesis plateaued, likely due to photoinhibitory effects, except for Navicula spp, which continued to accumulate lipids. Increasing under-ice light availability led to increased energy allocation towards carbohydrates, but this was secondary to lipid synthesis, while protein content remained stable. It is predicted that under-ice light availability will change in the Arctic, increasing due to sea-ice thinning and potentially decreasing with higher snowfall. Our findings show that the nutritional content of sea-ice diatoms are taxon-specific and linked to these changes, highlighting potential implications for future energy and nutrient supply for the polar marine food web.
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北极海冰硅藻的生物分子特征凸显了冰下光照在细胞能量分配中的作用
北极海冰硅藻为极地海洋食物网提供燃料,因为它们正从冬季的黑暗中步入春季。它们通过光合作用制造养分和能量,为次级生产提供支持。海冰硅藻的丰度和生物分子组成随时间和空间而变化。随着气候变化造成短期极端环境条件和长期平均环境条件的变化,了解硅藻如何以及以何种方式随着环境扰动调整生物分子储存,对于深入了解未来生态系统的能量生产和营养物质转移非常重要。利用同步辐射傅立叶变换红外微光谱技术,我们研究了挪威斯瓦尔巴群岛春季冰下光照条件范围内陆地冰群落中五个主要海冰硅藻类群的生物分子组成。当透射到冰水界面的光>5%但<15%(冰雪衰减 85-95%)时,我们发现所有五个类群的脂质和脂肪酸含量都翻了一番。我们确定了透光率在 15%左右时的临界值,在此临界值之后,生物分子合成趋于平稳,这可能是由于光抑制作用,但 Navicula spp 除此以外,脂质继续积累。冰下光照的增加导致碳水化合物的能量分配增加,但这对脂质合成是次要的,而蛋白质含量保持稳定。据预测,北极地区的冰下光照将发生变化,海冰变薄会导致冰下光照增加,降雪量增加则可能导致冰下光照减少。我们的研究结果表明,海冰硅藻的营养成分具有类群特异性,并与这些变化相关联,这凸显了对极地海洋食物网未来能量和营养供应的潜在影响。
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