{"title":"Interplay between CO<sub>2</sub> and light governs carbon partitioning in Chlamydomonas reinhardtii.","authors":"Luca Zuliani, Michela Cecchin, Tea Miotti, Matteo Paloschi, Stephan Cuine, Stefano Cazzaniga, Yonghua Li-Beisson, Matteo Ballottari","doi":"10.1111/ppl.14630","DOIUrl":null,"url":null,"abstract":"<p><p>Increasing CO<sub>2</sub> availability is a common practice at the industrial level to trigger biomass productivity in microalgae cultures. Still, the consequences of high CO<sub>2</sub> availability in microalgal cells exposed to relatively high light require further investigation. Here, the photosynthetic, physiologic, and metabolic responses of the green microalga model Chlamydomonas reinhardtii were investigated in high or low CO<sub>2</sub> availability conditions: high CO<sub>2</sub> enabled higher biomass yields only if sufficient light energy was provided. Moreover, cells grown in high light and high CO<sub>2</sub> availability were characterized, compared to cells grown in high light and low CO<sub>2</sub>, by a relative increase of the energy-dense triacylglycerols and decreased starch accumulation per dry weight. The photosynthetic machinery adapted to the increased carbon availability, modulating Photosystem II light-harvesting efficiency and increasing Photosystem I photochemical activity, which shifted from being acceptor side to donor side limited: cells grown at high CO<sub>2</sub> availability were characterized by increased photosynthetic linear electron flow and by the onset of a balance between NAD(P)H oxidation and NAD(P)<sup>+</sup> reduction. Mitochondrial respiration was also influenced by the conditions herein applied, with reduced respiration through the cytochrome pathway compensated by increased respiration through alternative pathways, demonstrating a different use of the cellular reducing power based on carbon availability. The results suggest that at high CO<sub>2</sub> availability and high irradiance, the reducing power generated by the oxidative metabolism of photosynthates is either dissipated through alternative oxidative pathways in the mitochondria or translocated back to the chloroplasts to support carbon assimilation and energy-rich lipids accumulation.</p>","PeriodicalId":20164,"journal":{"name":"Physiologia plantarum","volume":"176 6","pages":"e14630"},"PeriodicalIF":5.4000,"publicationDate":"2024-11-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Physiologia plantarum","FirstCategoryId":"99","ListUrlMain":"https://doi.org/10.1111/ppl.14630","RegionNum":2,"RegionCategory":"生物学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"PLANT SCIENCES","Score":null,"Total":0}
引用次数: 0
Abstract
Increasing CO2 availability is a common practice at the industrial level to trigger biomass productivity in microalgae cultures. Still, the consequences of high CO2 availability in microalgal cells exposed to relatively high light require further investigation. Here, the photosynthetic, physiologic, and metabolic responses of the green microalga model Chlamydomonas reinhardtii were investigated in high or low CO2 availability conditions: high CO2 enabled higher biomass yields only if sufficient light energy was provided. Moreover, cells grown in high light and high CO2 availability were characterized, compared to cells grown in high light and low CO2, by a relative increase of the energy-dense triacylglycerols and decreased starch accumulation per dry weight. The photosynthetic machinery adapted to the increased carbon availability, modulating Photosystem II light-harvesting efficiency and increasing Photosystem I photochemical activity, which shifted from being acceptor side to donor side limited: cells grown at high CO2 availability were characterized by increased photosynthetic linear electron flow and by the onset of a balance between NAD(P)H oxidation and NAD(P)+ reduction. Mitochondrial respiration was also influenced by the conditions herein applied, with reduced respiration through the cytochrome pathway compensated by increased respiration through alternative pathways, demonstrating a different use of the cellular reducing power based on carbon availability. The results suggest that at high CO2 availability and high irradiance, the reducing power generated by the oxidative metabolism of photosynthates is either dissipated through alternative oxidative pathways in the mitochondria or translocated back to the chloroplasts to support carbon assimilation and energy-rich lipids accumulation.
增加二氧化碳的供应量是工业领域的一种常见做法,以提高微藻培养的生物量生产率。然而,高二氧化碳供应量对暴露在相对强光下的微藻细胞的影响还需要进一步研究。本文研究了绿色微藻模型莱茵衣藻(Chlamydomonas reinhardtii)在高或低二氧化碳供应条件下的光合作用、生理和代谢反应:只有提供充足的光能,高二氧化碳才能提高生物量产量。此外,与在高光照和低二氧化碳条件下生长的细胞相比,在高光照和高二氧化碳条件下生长的细胞的特点是高能量的三酰甘油相对增加,单位干重的淀粉积累减少。光合作用机制适应了碳供应量的增加,调节了光系统 II 的光收集效率,提高了光系统 I 的光化学活性,使其从受体方受限转变为供体方受限:在高二氧化碳供应量下生长的细胞的特点是光合作用线性电子流增加,NAD(P)H 氧化和 NAD(P)+ 还原之间开始平衡。线粒体呼吸也受到所应用条件的影响,通过细胞色素途径减少的呼吸量被通过替代途径增加的呼吸量所补偿,这表明细胞还原力的使用因碳的可用性而不同。结果表明,在高二氧化碳供应量和高辐照度条件下,光合产物氧化代谢产生的还原力要么通过线粒体中的替代氧化途径耗散,要么转移回叶绿体以支持碳同化和富含能量的脂质积累。
期刊介绍:
Physiologia Plantarum is an international journal committed to publishing the best full-length original research papers that advance our understanding of primary mechanisms of plant development, growth and productivity as well as plant interactions with the biotic and abiotic environment. All organisational levels of experimental plant biology – from molecular and cell biology, biochemistry and biophysics to ecophysiology and global change biology – fall within the scope of the journal. The content is distributed between 5 main subject areas supervised by Subject Editors specialised in the respective domain: (1) biochemistry and metabolism, (2) ecophysiology, stress and adaptation, (3) uptake, transport and assimilation, (4) development, growth and differentiation, (5) photobiology and photosynthesis.