Crossed wires: diatom phosphate sensing mechanisms coordinate nitrogen metabolism.

Plant signaling & behavior Pub Date : 2024-12-31 Epub Date: 2024-10-02 DOI:10.1080/15592324.2024.2404352
Yasmin Meeda, Ellen Harrison, Adam Monier, Glen Wheeler, Katherine E Helliwell
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Abstract

Phytoplankton can encounter dynamic changes in their environment including fluctuating nutrient supply, and therefore require survival mechanisms to compete for such growth-limiting resources. Diatoms, single-celled eukaryotic microalgae, are typically first responders when crucial macronutrients phosphorus (P) and nitrogen (N) enter the marine environment and therefore must have tightly regulated nutrient sensory systems. While nutrient starvation responses have been described, comparatively little is known about diatom nutrient sensing mechanisms. We previously identified that the model diatoms Phaeodactylum tricornutum and Thalassiosira pseudonana use calcium (Ca2+) ions as a rapid intracellular signaling response following phosphate resupply. This response is evident only in phosphate deplete conditions, suggesting that it is coordinated in P-starved cells. Rapid increases in N uptake and assimilation pathways observed following phosphate resupply, indicate tight interplay between P and N signaling. To regulate such downstream changes, Ca2+ ions must bind to Ca2+ sensors following phosphate induced Ca2+ signals, yet this molecular machinery is unknown. Here, we describe our findings in relation to known diatom P starvation signaling mechanisms and discuss their implications in the context of environmental macronutrient metadata and in light of recent developments in the field. We also consider the importance of studying phytoplankton nutrient signaling systems in the face of future ocean conditions.

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交叉的电线:硅藻磷酸盐传感机制协调氮代谢。
浮游植物可能会遇到环境的动态变化,包括营养供应的波动,因此需要生存机制来争夺这些限制生长的资源。硅藻是单细胞真核微型藻类,当关键的大量营养元素磷(P)和氮(N)进入海洋环境时,硅藻通常是第一反应者,因此必须拥有严格调节的营养感知系统。虽然人们已经描述了营养饥饿反应,但对硅藻营养传感机制的了解却相对较少。我们之前发现,模式硅藻 Phaeodactylum tricornutum 和 Thalassiosira pseudonana 在磷酸盐补给后利用钙(Ca2+)离子作为快速的细胞内信号反应。这种反应只有在磷酸盐耗尽的条件下才会明显出现,这表明这种反应在缺磷细胞中是协调的。磷酸盐补给后,氮的吸收和同化途径迅速增加,这表明磷和氮的信号传递之间存在紧密的相互作用。为了调节这种下游变化,Ca2+ 离子必须在磷酸盐诱导 Ca2+ 信号后与 Ca2+ 传感器结合,但这种分子机制尚不清楚。在此,我们将结合已知的硅藻磷饥饿信号机制描述我们的发现,并结合环境宏量营养元素元数据和该领域的最新进展讨论其意义。我们还考虑了在未来海洋条件下研究浮游植物营养信号系统的重要性。
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