Light quality affects chlorophyll biosynthesis and photosynthetic performance in Antarctic Chlamydomonas

Marina Cvetkovska, Mackenzie Poirier, Kassandra Fugard
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Abstract

The perennially ice-covered Lake Bonney in Antarctica has been deemed a natural laboratory for studying life at the extreme. Photosynthetic algae dominate the lake food webs and are adapted to a multitude of extreme conditions including perpetual shading even at the height of the austral summer. Here we examine how the unique light environment in Lake Bonney influences the physiology of two Chlamydomonas species. Chlamydomonas priscuii is found exclusively in the deep photic zone where is receives very low light levels biased in the blue part of the spectrum (400-500 nm). In contrast, Chlamydomonas sp. ICE-MDV is represented at various depths within the water column (including the bright surface waters), and it receives a broad range of light levels and spectral wavelengths. The close phylogenetic relationship and psychrophilic character of both species makes them an ideal system to study the effects of light quality and quantity on chlorophyll biosynthesis and photosynthetic performance in extreme conditions. We show that the shade-adapted C. priscuii exhibits a decreased ability to accumulate chlorophyll and severe photoinhibition when grown under red light compared to blue light. These effects are particularly pronounced under red light of higher intensity, suggesting a loss of capability to acclimate to varied light conditions. In contrast, ICE-MDV has retained the ability to synthesize chlorophyll and maintain photosynthetic efficiency under a broader range of light conditions. Our findings provide insights into the mechanisms of photosynthesis under extreme conditions, and have implications on algal survival in changing conditions of Antarctic ice-covered lakes.
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光质影响南极衣藻的叶绿素生物合成和光合作用性能
南极洲常年冰封的邦尼湖被视为研究极端生命的天然实验室。光合藻类在湖泊食物网中占主导地位,并能适应多种极端条件,包括即使在盛夏时节也长期遮光。在此,我们研究了邦尼湖独特的光照环境如何影响两种衣藻的生理机能。普氏衣藻(Chlamydomonas priscuii)只生活在深光照区,那里的光照度非常低,偏向于光谱的蓝色部分(400-500 nm)。相比之下,ICE-MDV 衣藻则分布在水体的不同深度(包括明亮的表层水),接受的光照强度和光谱波长范围很广。这两个物种具有密切的系统发育关系和心理亲水性,因此是研究极端条件下光质和光量对叶绿素生物合成和光合作用性能影响的理想系统。我们的研究表明,与蓝光相比,在红光下生长的适应遮荫的 C. priscuii 表现出叶绿素积累能力下降和严重的光抑制。这些影响在更高强度的红光下尤为明显,表明其丧失了适应不同光照条件的能力。相比之下,ICE-MDV 在更广泛的光照条件下仍能合成叶绿素并保持光合效率。我们的研究结果为极端条件下的光合作用机制提供了启示,并对南极冰封湖泊中不断变化的条件下藻类的生存产生了影响。
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