Krausfeldt Lauren E, Samuel Paisley S, Smith Robert P, Urakawa Hidetoshi, Rosen Barry H, Colwell Rita R, Lopez Jose V
Department of Biological Sciences, Guy Harvey Oceanographic Center, Nova Southeastern University, Dania Beach, Florida, USA.
Cell Therapy Institute, Kiran Patel College of Allopathic Medicine, Nova Southeastern University, Fort Lauderdale, Florida, USA.
Microbiol Spectr. 2025 Jan 7;13(1):e0136924. doi: 10.1128/spectrum.01369-24. Epub 2024 Nov 18.
Harmful algal blooms caused by cyanobacteria threaten aquatic ecosystems, the economy, and human health. Previous work has tried to identify the mechanisms that allow blooms to form, focusing on the role of nutrients. However, little is known about how introduced nutrients influence gene expression . To address this knowledge gap, we used mesocosms initiated with water experiencing a bloom. We added pulses of nutrients that are commonly associated with anthropogenic sources to the mesocosms for 72 hours and collected samples for metatranscriptomics to examine how the physiological function of and bloom status changed. The addition of nitrogen (N) as urea, but not the addition of PO, resulted in conspicuous bloom persistence for at least 9 days after the final introduction of nutrients. The addition of urea initially resulted in the upregulation of photosynthesis machinery, as well as phosphate, carbon, and N transport and metabolism. Once presumably became N-replete, upregulation of amino acid metabolism, microcystin biosynthesis, and other processes associated with biomass generation occurred. These capacities coincided with the upregulation of toxin-antitoxin systems, CRISPR- genes, and transposases suggesting that phage defense and genome rearrangement are critical in bloom persistence. Overall, our results show the stepwise transcriptional response of a bloom to the introduction of nutrients, specifically urea, as it is sustained in a natural setting. The transcriptomic shifts observed herein may serve as markers of the longevity of blooms while providing insight into why blooms over other cyanobacteria.IMPORTANCEHarmful algal blooms represent a threat to human health and ecosystems. Understanding why blooms persist may help us develop warning indicators of bloom persistence and create novel mitigation strategies. Using mesocosm experiments initiated with water with an active bloom, we measured the stepwise transcription changes of the toxin-producing cyanobacterium in response to the addition of nutrients that are important in causing blooms. We found that nitrogen (N), but not phosphorus, promoted bloom longevity. The initial introduction of N resulted in the upregulation of genes involved in photosynthesis and N import. At later times in the bloom, upregulation of genes involved in biomass generation, phage protection, genomic rearrangement, and toxin production was observed. Our results suggest that first fulfills nutritional requirements before investing energy in pathways associated with growth and protection against competitors, which allowed bloom persistence more than a week after the final addition of nutrients.
由蓝藻引起的有害藻华威胁着水生生态系统、经济和人类健康。此前的研究试图确定藻华形成的机制,重点关注营养物质的作用。然而,对于引入的营养物质如何影响基因表达却知之甚少。为了填补这一知识空白,我们使用了起始于正在经历藻华的水体的中型生态系统。我们向中型生态系统中添加了通常与人为来源相关的营养脉冲,持续72小时,并收集样本进行宏转录组学分析,以研究[具体藻类名称未给出]的生理功能和藻华状态如何变化。添加尿素形式的氮(N),而不是添加磷(PO),导致在最后一次引入营养物质后至少9天内藻华持续存在且十分明显。添加尿素最初导致光合作用机制以及磷酸盐、碳和氮的运输与代谢上调。一旦[具体藻类名称未给出]可能氮充足,氨基酸代谢、微囊藻毒素生物合成以及其他与生物量生成相关的过程就会上调。这些能力与毒素 - 抗毒素系统、CRISPR - [具体基因名称未给出]基因和转座酶的上调同时出现,这表明噬菌体防御和基因组重排对于藻华持续存在至关重要。总体而言,我们的结果显示了[具体藻类名称未给出]藻华对营养物质(特别是尿素)引入的逐步转录反应,因为它在自然环境中持续存在。本文观察到的转录组变化可作为藻华持续时间的标志物,同时有助于深入了解[具体藻类名称未给出]藻华超过其他蓝藻的原因。
重要性
有害藻华对人类健康和生态系统构成威胁。了解藻华为何持续存在可能有助于我们开发藻华持续存在的预警指标,并制定新的缓解策略。通过使用起始于活跃藻华水体的中型生态系统实验,我们测量了产毒蓝藻[具体藻类名称未给出]对导致藻华的重要营养物质添加的逐步转录变化。我们发现氮(N)而非磷促进了藻华的持续时间。最初引入氮导致参与光合作用和氮吸收的基因上调。在藻华后期,观察到参与生物量生成、噬菌体保护、基因组重排和毒素产生的基因上调。我们的结果表明,[具体藻类名称未给出]首先满足营养需求,然后才将能量投入到与生长和抵御竞争者相关的途径中,这使得在最后一次添加营养物质后藻华持续了一周多时间。
