Pathways of copper acquisition in phytoplankton

浮游植物获取铜的途径

• 批准号: RGPIN-2020-04487
• 负责人: Price, Neil
• 金额: $ 2.04万
• 依托单位: McGill University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2020
• 资助国家: 加拿大
• 起止时间: 2020-01-01 至 2021-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=717029
• 关键词: Pathways; copper; acquisition; phytoplankton

Metal uptake by phytoplankton is fundamentally important because it links the reactivity of metals in the environment to their physiological and ecological effects in the organisms. Understanding how metals are taken up enables us to predict which chemical forms of metals are bioavailable and which types of phytoplankton will respond to changes in their concentrations. Diatoms and cyanobacteria are two groups of phytoplankton of great significance to aquatic ecosystems. They grow in the open sea in surface waters containing some of lowest levels of metals on Earth although they are exposed to high concentrations transiently because of inputs from dust and upwelling from deep waters. Copper (Cu) is of interest because it is an essential metal for phytoplankton growth and one of the most toxic. Phytoplankton adjust their uptake systems to buffer changes in metal concentrations in the environment to maintain optimal cellular levels, but the details of the uptake pathways are only now being revealed. Copper is utilized by oceanic diatoms by an uptake pathway that uses a chemically reduced form of Cu, Cu(I). The Cu(I) is produced by cellular reduction, but little is known about how cellular reduction is regulated or whether other phytoplankton acquire Cu in the same way. Other groups, like cyanobacteria, may use different pathways for Cu uptake and hence react to different chemical forms of Cu than diatoms. Cyanobacteria, for example, produce compounds that bind Cu to detoxify it, changing the chemistry of Cu in the water and thereby altering its availability to other species. The aims of this research proposal are: 1) to measure the bioavailability of Cu chemical species as a function of Cu nutritional state of diatoms and cyanobacteria, 2) to assess the prevalence of the Cu(II) reduction uptake pathway among different taxonomic groups of phytoplankton and its activation by light, and 3) to describe the Cu-regulated transcriptome of two cyanobacteria and identify differentially expressed genes including putative Cu transport genes induced by Cu deficiency. The proposed research is part of a continuing effort to elucidate the factors regulating phytoplankton growth in the sea. It will provide a mechanistic understanding of Cu uptake by representatives of two ecologically important groups of phytoplankton and identify the potential ecological and biogeochemical consequences of variations in Cu availability. The work is timely given that ocean acidification is predicted to greatly increase the concentration of some inorganic species of Cu and affect Cu complexation by dissolved organic matter. How phytoplankton will be affected by these changes is uncertain as we have a rudimentary understanding of their mechanisms of Cu uptake and know little about the types of Cu species that are available for cellular transport. The research outlined here will begin to fill these gaps in knowledge.

浮游植物对金属的吸收至关重要，因为它将环境中金属的反应性与生物体的生理和生态效应联系起来。 了解金属是如何被吸收的，使我们能够预测哪些化学形式的金属是生物可利用的，以及哪些类型的浮游植物将对其浓度的变化做出反应。 硅藻和蓝藻是对水生生态系统具有重要意义的两类浮游植物。 它们生长在地球上金属含量最低的表层沃茨的公海中，尽管由于灰尘和深层沃茨的涌升，它们会短暂地暴露在高浓度的环境中。 铜（Cu）是感兴趣的，因为它是浮游植物生长的必需金属，也是毒性最大的金属之一。 浮游植物调整其吸收系统，以缓冲环境中金属浓度的变化，以保持最佳的细胞水平，但吸收途径的细节现在才被揭示。 铜被海洋硅藻利用的吸收途径，使用化学还原形式的铜，铜（I）。 铜（I）是由细胞还原产生的，但很少有人知道细胞还原是如何调节的，或者其他浮游植物是否以同样的方式获得铜。 其他群体，如蓝细菌，可能使用不同的途径吸收铜，因此反应不同的化学形式的铜比硅藻。 例如，蓝细菌产生结合铜的化合物来解毒，改变水中铜的化学性质，从而改变其对其他物种的可用性。 本研究提案的目的是：1）测量作为硅藻和蓝细菌Cu营养状态的函数的Cu化学物种的生物利用度，2）评估不同分类组的浮游植物中Cu（II）还原吸收途径的普遍性及其被光激活，3）描述两种蓝细菌的铜调节转录组，并鉴定差异表达的基因，包括铜缺乏诱导的推定铜转运基因。这项拟议中的研究是持续努力阐明调节海洋浮游植物生长的因素的一部分。 它将提供一个机械的理解，铜吸收的两个生态上重要的浮游植物群体的代表，并确定潜在的生态和地球化学后果的变化，铜的可用性。由于预测海洋酸化将大大增加某些无机Cu物种的浓度，并影响溶解有机物对Cu的络合作用，因此这项工作是及时的。 浮游植物将如何受到这些变化的影响是不确定的，因为我们有一个初步的了解，他们的机制，铜的吸收和知之甚少的类型的铜物种，可用于细胞运输。 这里概述的研究将开始填补这些知识空白。