Large Lakes Observatory, University of Minnesota Duluth, Duluth, MN 55812, United States.
National Park Service, Ashland, WI, United States.
Harmful Algae. 2020 Dec;100:101941. doi: 10.1016/j.hal.2020.101941. Epub 2020 Nov 14.
Lake Superior has recently begun experiencing cyanobacterial blooms comprised of Dolichospermum lemmermannii near the Apostle Islands and along the southern shore of the western arm. Little is known about the origin of these blooms. Experiments were conducted during the summers of 2017 and 2018 to identify sources of propagules and characteristics of sites that were potential sources. The 2017 experiments were conducted using a factorial design with three source zones ('River', 'Lake', and 'Harbor'), two nutrient conditions (high and low N:P), and three temperatures (15, 20, and 25°C). At the end of the experiment, cyanobacteria were most abundant from the 'River' and 'Harbor' zones at low N:P and 20 and 25°C, with D. lemmermannii most abundant at 20°C. Subsequently, in 2018 we evaluated 26 specific inland locations from three waterbody types ('River', 'Lake/Pond', and 'Coastal') and explored similarities among those sites that produced cyanobacteria in high abundance when samples were incubated under optimal conditions (low N:P and 25°C). Under these growing conditions, we found high cyanobacteria abundance developed in samples from river sites with low ambient temperatures and high conductivity. Field monitoring showed that Lake Superior nearshore temperatures were higher than rivers. These observations suggest that blooms of D. lemmermannii in Lake Superior are initiated by fluvial seeding of propagules and highlight the importance of warmer temperatures and favorable nutrient and light conditions for subsequent extensive cyanobacterial growth. We argue that the watershed is an important source of biological loading of D. lemmermannii to Lake Superior and that when those cells reach the nearshore where there are warmer water temperatures and increased light, they can grow in abundance to produce blooms.
苏必利尔湖最近开始出现由水华束丝藻组成的蓝藻水华,这些水华位于阿波斯特尔群岛附近和西部海湾的南岸。这些水华的起源知之甚少。2017 年和 2018 年夏季进行了实验,以确定繁殖体的来源和可能的来源地点的特征。2017 年的实验采用了三因素设计,包括三个源区('River'、'Lake'和'Harbor')、两种营养条件(高氮磷比和低氮磷比)和三个温度(15、20 和 25°C)。实验结束时,在低氮磷比和 20 和 25°C 条件下,来自'River'和'Harbor'区的蓝藻最为丰富,水华束丝藻在 20°C 时最为丰富。随后,在 2018 年,我们评估了来自三种水体类型('River'、'Lake/Pond'和'Coastal')的 26 个特定内陆地点,并探索了在最佳条件(低氮磷比和 25°C)下培养时产生高丰度蓝藻的那些地点之间的相似性。在这些生长条件下,我们发现来自环境温度低、电导率高的河流站点的样品中蓝藻丰度较高。现场监测表明,苏必利尔湖近岸温度高于河流。这些观察结果表明,苏必利尔湖水华束丝藻的爆发是由繁殖体的河流播种引发的,并强调了温暖的温度和有利的营养和光照条件对随后广泛的蓝藻生长的重要性。我们认为,流域是水华束丝藻向苏必利尔湖输入生物负荷的重要来源,当这些细胞到达近岸地区,那里有更温暖的水温和增加的光照时,它们可以大量生长并产生水华。
