School of Earth and Environmental Sciences, College of Natural Sciences, Seoul National University, Seoul 08826, Republic of Korea.
School of Earth and Environmental Sciences, College of Natural Sciences, Seoul National University, Seoul 08826, Republic of Korea; Advanced Institutes of Convergence Technology, Suwon, Gyeonggi-do 16229, Republic of Korea.
Harmful Algae. 2016 Nov;59:67-81. doi: 10.1016/j.hal.2016.09.008. Epub 2016 Oct 7.
The dinoflagellate Alexandrium spp. have received much attention due to their harmful effects on diverse marine organisms, including commercially important species. For minimizing loss due to red tides or blooms of Alexandrium spp., it is very important to understand the eco-physiology of each Alexandrium species and to predict its population dynamics. Its trophic mode (i.e., exclusively autotrophic or mixotrophic) is one of the most critical parameters in establishing prediction models. However, among the 35 Alexandrium species so far described, only six Alexandrium species have been revealed to be mixotrophic. Thus, mixotrophic ability of the other Alexandrium species should be explored. In the present study, whether each of three Alexandrium species (A. andersonii, A. affine, and A. fraterculus) isolated from Korean waters has or lacks mixotrophic ability, was investigated. When diets of diverse algal prey, cyanobacteria, and bacteria sized micro-beads were provided, A. andersonii was able to feed on the prasinophyte Pyramimonas sp., the cryptophyte Teleaulax sp., and the dinoflagellate Heterocapsa rotundata, whereas neither A. affine nor A. fraterculus fed on any prey item. Moreover, mixotrophy elevated the growth rate of A. andersonii. The maximum mixotrophic growth rates of A. andersonii on Pyramimonas sp. under a 14:10h light/dark cycle of 20μEms was 0.432d, while the autotrophic growth rate was 0.243d. With increasing mean prey concentration, the ingestion rate of A. andersonii increased rapidly at prey concentrations <650ngCml (ca. 16,240 cellsml), but became saturated at the higher prey concentrations. The maximum ingestion rate by A. andersonii of Pyramimonas sp. was 1.03ngC predatord (25.6 cells predatord). This evidence suggests that the mixotrophic ability of A. andersonii should be taken into consideration in predicting the outbreak, persistence, and decline of its harmful algal blooms.
甲藻属的亚历山大藻因其对各种海洋生物的有害影响而备受关注,包括商业上重要的物种。为了最大限度地减少因赤潮或亚历山大藻属的大量繁殖而造成的损失,了解每个亚历山大藻种的生态生理学并预测其种群动态非常重要。其营养方式(即专性自养或混合营养)是建立预测模型的最重要参数之一。然而,在迄今描述的 35 种亚历山大藻中,仅有 6 种被揭示为混合营养。因此,应该探索其他亚历山大藻的混合营养能力。在本研究中,研究了从韩国水域分离的三种亚历山大藻(A. andersonii、A. affine 和 A. fraterculus)是否具有或缺乏混合营养能力。当提供不同藻类猎物、蓝细菌和细菌大小的微珠作为食物时,A. andersonii 能够以原甲藻 Pyramimonas sp.、隐藻 Teleaulax sp. 和甲藻 Heterocapsa rotundata 为食,而 A. affine 和 A. fraterculus 则不能以任何猎物为食。此外,混合营养会提高 A. andersonii 的生长速度。在 20μEms 的 14:10h 光/暗循环下,A. andersonii 对 Pyramimonas sp. 的最大混合营养生长率为 0.432d,而自养生长率为 0.243d。随着平均猎物浓度的增加,A. andersonii 的摄食率在猎物浓度<650ngCml(约 16,240 个细胞/ml)时迅速增加,但在较高的猎物浓度下达到饱和。A. andersonii 对 Pyramimonas sp. 的最大摄食率为 1.03ngC 猎物(25.6 个猎物)。这表明,在预测其有害藻华的爆发、持续和衰退时,应考虑 A. andersonii 的混合营养能力。
