盗塑性细甲藻的生态生理学：I.韩国沿海水域的时空分布及生长和摄食率

IF 3.1 3区生物学 Q1 MARINE & FRESHWATER BIOLOGY

Algae Pub Date : 2021-12-15 DOI:10.4490/algae.2021.36.11.28

Jin Hee Ok, H. Jeong, Hee Chang Kang, Sang Ah Park, S. Eom, Ji Hyun You, Sung Yeon Lee

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引用次数: 10

摘要

为了探索盗塑性细甲藻Shimella gracilenta的生态生理特征，我们确定了它在韩国沿海水域的时空分布以及生长和摄食率作为猎物浓度的函数。2015年至2018年，使用定量实时聚合酶链式反应测量了28个站点的薄梭菌丰度。当温度和盐度分别为1.7–26.4°C和9.9–35.6时，在所有站点和每个季节至少检测到一次薄梭菌细胞。此外，在测试的28种潜在猎物中，薄丝酵母SGJH1904以不同的猎物类群为食。然而，在研究期间，薄梭菌的最高丰度仅为3个细胞mL-1。gracilenta生长的Teleaulax两氧杂环己烷的阈值浓度为5618个细胞mL-1，远高于两氧杂环丁烷的最高丰度（667个细胞mL-1）。因此，在研究期间，T.amphoxeia不太可能支持薄梭菌在田间的生长。然而，薄梭菌对两氧西氏锥虫的最大比生长率和摄食率分别为1.36 d-1和0.04纳克C捕食者-1 d-1。因此，如果T.ampioxeia的丰度远高于5618个细胞mL-1，则S.gracilenta的丰度可能远高于本研究中观察到的最高丰度。薄丝酵母的Eurythermal和euryhaline特性及其以不同猎物为食和进行盗塑性行为的能力可能是其常见时空分布的原因。

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Ecophysiology of the kleptoplastidic dinoflagellate Shimiella gracilenta: I. spatiotemporal distribution in Korean coastal waters and growth and ingestion rates

To explore the ecophysiological characteristics of the kleptoplastidic dinoflagellate Shimiella gracilenta, we determined its spatiotemporal distribution in Korean coastal waters and growth and ingestion rates as a function of prey concentration. The abundance of S. gracilenta at 28 stations from 2015 to 2018 was measured using quantitative realtime polymerase chain reaction. Cells of S. gracilenta were detected at least once at all the stations and in each season, when temperature and salinity were 1.7–26.4°C and 9.9–35.6, respectively. Moreover, among the 28 potential prey species tested, S. gracilenta SGJH1904 fed on diverse prey taxa. However, the highest abundance of S. gracilenta was only 3 cells mL-1 during the study period. The threshold Teleaulax amphioxeia concentration for S. gracilenta growth was 5,618 cells mL-1, which was much higher than the highest abundance of T. amphioxeia (667 cells mL-1). Thus, T. amphioxeia was not likely to support the growth of S. gracilenta in the field during the study period. However, the maximum specific growth and ingestion rates of S. gracilenta on T. amphioxeia, the optimal prey species, were 1.36 d-1 and 0.04 ng C predator- 1 d-1, respectively. Thus, if the abundance of T. amphioxeia was much higher than 5,618 cells mL-1, the abundance of S. gracilenta could be much higher than the highest abundance observed in this study. Eurythermal and euryhaline characteristics of S. gracilenta and its ability to feed on diverse prey species and conduct kleptoplastidy are likely to be responsible for its common spatiotemporal distribution.

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来源期刊

Algae PLANT SCIENCES-

CiteScore

5.10

自引率

25.00%

发文量

期刊介绍： ALGAE is published by the Korean Society of Phycology and provides prompt publication of original works on phycology. ALGAE publishes articles on all aspects of phylogenetics and taxonomy, ecology and population biology, physiology and biochemistry, cell and molecular biology, and biotechnology and applied phycology. Checklists or equivalent manu-scripts may be considered for publication only if they contribute original information on taxonomy (e.g., new combinations), ecology or biogeography of more than just local relevance. Contributions may take the form of Original Research Articles, Research Notes, Review Articles and Book Reviews.