Abstract
Harmful algal blooms (HABs) caused by the pelagophyte Aureococcus anophagefferens have spread globally and are a threat to coastal ecosystems. Although some HAB mitigation techniques such as algal biocides can be effective, many such approaches can have negative consequences on the environment. Therefore, it is important to investigate alternative HAB mitigation approaches that are ecologically safe and commercially viable. Here, we examine the effects of two rhodophyte seaweeds, Gracilaria tikvahiae and Dasysiphonia japonica, on A. anophagefferens. During experiments, multiple A. anophagefferens strains were co-cultured with densities of seaweed encompassing a range of environmental and aquaculture settings (0.25–3.00 g L−1). The co-effects of nutrients, heterotrophic bacteria and pH were also assessed, and A. anophagefferens cell concentrations and photosynthetic efficiency were quantified. In nearly all experiments, G. tikvahiae and D. japonica significantly reduced A. anophagefferens cell concentrations in a dose-dependent manner, with the effectiveness of each seaweed depending primarily on both A. anophagefferens and seaweed densities. The algicidal effects of D. japonica were significantly stronger than G. tikvahiae and other algicidal seaweeds (e.g., Ulva spp.). Allelopathy was the most potent mechanism for inhibition of A. anophagefferens; heterotrophic bacteria, nutrient limitation and elevated pH appeared to have lesser co-effects. These findings, in conjunction with the well-known nutrient removal capacity of seaweeds, suggest that the temporal and spatial dynamics of these rhodophytes may influence brown tides in shallow estuaries and that the use of seaweeds such as G. tikvahiae in aquaculture may be a promising mitigation strategy for this and other HABs in coastal ecosystems.
Highlights
While harmful algal blooms (HABs) are natural phenomena that have occurred throughout documented history, the public health and economic impacts of such events have increased in frequency, severity and geographical distribution over the past two decades (Anderson et al 2012, 2021)
G. tikvahiae and D. japonica significantly reduced cell concentrations of cultured and wild A. anophagefferens in a dose-dependent manner, with the effectiveness of each seaweed varying with initial A. anophagefferens cell concentration, nutrient levels, nitrogen source, seaweed density and the presence of antibiotics
At lower initial A. anophagefferens concentrations and with low nutrients, A. anophagefferens was most resistant to G. tikvahiae and D. japonica with 1.00 g L −1 of both species required to reduce cell concentrations after 72 h
Summary
While harmful algal blooms (HABs) are natural phenomena that have occurred throughout documented history, the public health and economic impacts of such events have increased in frequency, severity and geographical distribution over the past two decades (Anderson et al 2012, 2021). There has been a statistically significant increase in all HAB events combined in the USA since 1990 (Anderson et al 2021) and the coastal northeastern USA is emblematic of these trends, as, over the past several decades, it has increasingly experienced multiple HABs that had previously been unknown in the region (Anderson et al 2008, 2021). One such HAB in this region is caused by the picoplankton, Aureococcus anophagefferens, colloquially known as “brown tide.”. The onset of severe brown tides in New York (NY) nearly eliminated Long Island’s bay scallop (Argopecten irradians) population by causing extensive recruitment
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