Single-cell metabolome profiling for phenotyping parasitic diseases in phytoplankton

M. Vallet, Filip Kaftan, A. Buaya, M. Thines, L. Guillou, A. Svatoš, G. Pohnert
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Abstract

Bloom-forming phytoplankton are key players in aquatic ecosystems, fixing carbon dioxide and forming the base of the marine food web. Diverse stresses, such as nutrient depletion, temperature increase, and pathogen emergence can influence the health and dynamics of algal populations. While population responses to these stressors are well-documented in the aquatic ecosystems, little is known about the individual cellular adaptations. These are however the key to an in-depth physiological understanding of microbiome dynamics in the plankton. Finding solutions to disease control in aquaculture also depends on knowledge of infection dynamics and physiology in algae. Single-cell metabolomics can give insight into infection processes by providing a snapshot of small molecules within a biological system. We used a single-cell metabolome profiling workflow to track metabolic changes of diatoms and dinoflagellates subjected to parasite infection caused by the oomycete Lagenisma coscinodisci and the alveolate Parvilucifera spp. We accurately classified the healthy phenotype of bloom-forming phytoplankton, including the diatoms Coscinodiscus granii and Coscinodiscus radiatus, and the toxic dinoflagellate Alexandrium minutum. We discriminated the infection of the toxic dinoflagellate A. minutum with the alveolate parasitoids Parvilucifera infectans and P. rostrata down to the single-cell resolution. Strain and species-specific responses of the diatom hosts Coscinodiscus spp. Infected with the oomycete pathogen Lagenisma coscinodisci could be recognized. LC-HRMS and fragmentation pattern analysis enabled the structure elucidation of metabolic predictors of infection (guanine, xanthine, DMSP, and pheophorbide). The purine salvage pathway and DMSP lysis could be assigned as regulated processes during host invasion. The findings establish single-cell metabolome profiling with LDI-HRMS coupled with classification analysis as a reliable diagnostic tool to track metabolic changes in algae.
浮游植物寄生虫病表型的单细胞代谢组分析
形成水华的浮游植物是水生生态系统的关键参与者,固定二氧化碳并形成海洋食物网的基础。不同的压力,如营养物质消耗、温度升高和病原体出现,都会影响藻类种群的健康和动态。虽然种群对这些压力源的反应在水生生态系统中有充分的记录,但对个体细胞的适应却知之甚少。然而,这些是深入了解浮游生物微生物组动力学的关键。在水产养殖中寻找疾病控制的解决方案还取决于对藻类感染动力学和生理学的了解。单细胞代谢组学可以通过提供生物系统内小分子的快照来深入了解感染过程。我们使用单细胞代谢组分析工作流程来跟踪受到由卵菌Lagenisma coscinodisci和肺泡藻Parvilucifera spp.引起的寄生虫感染的硅藻和甲藻的代谢变化,以及有毒的甲藻微小亚历山大藻。我们将有毒甲藻A.minutum与肺泡状寄生蜂Parvilucifera infectians和P.rostrata的感染区分为单细胞分辨率。硅藻宿主Coscinodescp.的菌株和物种特异性反应。可以识别感染卵菌病原体Lagenisma coscinodesci的硅藻。LC-HRMS和碎片模式分析能够对感染的代谢预测因子(鸟嘌呤、黄嘌呤、DMSP和脱镁叶绿酸)进行结构阐明。嘌呤挽救途径和二甲基亚砜裂解可以被认为是宿主入侵过程中的调节过程。这些发现建立了用LDI-HRMS结合分类分析的单细胞代谢组分析,作为追踪藻类代谢变化的可靠诊断工具。
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