Transcriptome analysis revealed regulatory mechanisms of light and culture density on free-living sporangial filaments of Neopyropia yezoensis (Rhodophyta)
Bangxiang He, Zhenbing Zheng, J. Niu, Xiujun Xie, Guangce Wang
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引用次数: 0
Abstract
Previous research indicated that free-living sporangial filament keep hollow morph under high-culture density and form bipartite cells under low-culture density, while the following conchospore release was inhibited by high light. Here, we further explored the molecular bases of these affects caused by light and culture density using a transcriptome analysis. Many differentially expressed genes (DEGs) related to carbon dioxide concentration and fixation, photosynthesis, chlorophyll synthesis and nitrogen absorption were upregulated under high-light conditions compared with low-light conditions, indicating the molecular basis of rapid vegetative growth under the former. The stress response- and ion transport-related DEGs, as well as the gene encoding the vacuole formation–brefeldin A-inhibited guanine nucleotide exchange protein (BIG, py05721), were highly expressed under high-density conditions, indicating the molecular basis of the hollow morph of free-living sporangial filaments under high-culture density conditions. Additionally, the brefeldin A treatment indicated that the hollow morph was directly influenced by vacuole formation-related vesicle traffic. Others DEGs related to cell wall components, zinc-finger proteins, ASPO1527, cell cycle and cytoskeleton were highly expressed in the low density with low-light group, which might be related to the formation and release of conchospores. These results provide a deeper understanding of sporangial filaments in Neopyropia yezoensis and related species.
以前的研究表明,自由生活的孢子囊丝在高培养密度下保持中空形态,在低培养密度下形成双分化细胞,而随后的分生孢子释放受到强光的抑制。在此,我们利用转录组分析进一步探讨了光照和培养密度造成这些影响的分子基础。与低光照条件相比,许多与二氧化碳浓度和固定、光合作用、叶绿素合成和氮吸收相关的差异表达基因(DEGs)在高光照条件下上调,这表明前者是无性快速生长的分子基础。在高密度条件下,与应激反应和离子转运相关的 DEGs 以及编码液泡形成-brefeldin A 抑制鸟嘌呤核苷酸交换蛋白(BIG,py05721)的基因均高表达,这表明高培养密度条件下自由生活孢子丝中空形态的分子基础。此外,brefeldin A 处理表明中空形态直接受液泡形成相关囊泡交通的影响。其他与细胞壁成分、锌指蛋白、ASPO1527、细胞周期和细胞骨架相关的 DEGs 在低密度低光照组中高表达,这可能与球果的形成和释放有关。这些结果加深了对新叶藻及相关物种孢子囊丝的了解。
期刊介绍:
ALGAE is published by the Korean Society of Phycology and provides prompt publication of original works on phycology. ALGAE publishes articles on all aspects of phylogenetics and taxonomy, ecology and population biology, physiology and biochemistry, cell and molecular biology, and biotechnology and applied phycology. Checklists or equivalent manu-scripts may be considered for publication only if they contribute original information on taxonomy (e.g., new combinations), ecology or biogeography of more than just local relevance. Contributions may take the form of Original Research Articles, Research Notes, Review Articles and Book Reviews.