Dinophysis, a highly specialized mixoplanktonic protist

Frontiers in Protistology Pub Date : 2024-01-08 DOI:10.3389/frpro.2023.1328026

Beatriz Reguera, María García-Portela, Esther Velasco-Senovilla, P. Rial, Laura Escalera, Patricio A. Díaz, Francisco Rodríguez

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引用次数: 1

Abstract

Several Dinophysis species produce lipophilic toxins (diarrhetic shellfish poisoning, DSP and pectenotoxins PTX) which are transferred through the food web. Even at low cell densities (< 103 cell L-1), they can cause human illness and shellfish harvesting bans; toxins released into the water may kill early life stages of marine organisms. Dinophysis species are mixotrophs: they combine phototrophy (by means of kleptoplastids stolen from their prey) with highly selective phagotrophy on the ciliate Mesodinium, also a mixotroph which requires cryptophyte prey of the Teleaulax/Geminigera clade. Life cycle strategies, biological interactions and plastid acquisition and functioning in Dinophysis species make them exemplars of resilient holoplanktonic mixoplankters and of ongoing speciation and plastidial evolution. Nevertheless, 17 years after the first successful culture was established, the difficulties in isolating and establishing cultures with local ciliate prey, the lack of robust molecular markers for species discrimination, and the patchy distribution of low-density populations in thin layers, hinder physiological experiments to obtain biological measurements of their populations and slow down potential advances with next-generation technologies. The Omic’s age in Dinophysis research has only just started, but increased efforts need to be invested in systematic studies of plastidic diversity and culture establishment of ciliate and cryptophyte co-occurring with Dinophysis in the same planktonic assemblages.

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Dinophysis，一种高度特化的混合浮游原生动物

一些 Dinophysis 物种会产生亲脂性毒素（腹泻性贝类中毒、DSP 和果核毒素 PTX），这些毒素会通过食物网传播。即使细胞密度较低（< 103 cells L-1），它们也会导致人类疾病和贝类捕捞禁令；释放到水中的毒素可能会杀死海洋生物的早期生命阶段。Dinophysis 物种是一种混养生物：它们将光能营养（通过从猎物身上窃取的隐球体）与对纤毛虫 Mesodinium 的高度选择性吞噬作用结合起来，Mesodinium 也是一种混养生物，需要 Teleaulax/Geminigera 支系的隐球体猎物。Dinophysis 物种的生命周期策略、生物相互作用以及质体的获得和功能使它们成为具有复原能力的全浮游混合浮游生物以及持续的物种演化和质体进化的典范。然而，在建立第一个成功的培养物 17 年后的今天，与当地纤毛虫猎物分离和建立培养物的困难、缺乏用于物种鉴别的可靠分子标记，以及薄层中低密度种群的零星分布，都阻碍了对其种群进行生物学测量的生理实验，并延缓了下一代技术的潜在进展。Dinophysis 研究的 "Omic 时代 "才刚刚开始，但需要加大力度系统研究质体多样性，并建立与 Dinophysis 共存于同一浮游生物群中的纤毛虫和隐花植物的培养体系。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Frontiers in Protistology

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