Abstract
Aquaculture is a rapidly expanding industry and is now one of the primary sources of all consumed seafood. Intensive aquaculture production is associated with organic enrichment, which occurs as organic material settles onto the seafloor, creating anoxic conditions which disrupt ecological processes. Bacteria are sensitive bioindicators of organic enrichment, and supervised classifiers using features derived from 16s rRNA gene sequences have shown potential to become useful in aquaculture environmental monitoring. Current taxonomy-based approaches, however, are time intensive and built upon emergent features which cannot easily be condensed into a monitoring pipeline. Here, we used a taxonomy-free approach to examine 16s rRNA gene sequences derived from flocculent matter underneath and in proximity to hard-bottom salmon aquaculture sites in Newfoundland, Canada. Tetranucleotide frequencies (k = 4) were tabulated from sample sequences and included as features in a machine learning pipeline using the random forest algorithm to predict 4 levels of benthic disturbance; resulting classifications were compared to those obtained using a published taxonomy-based approach. Our results show that k-mer count features can effectively be used to create highly accurate predictions of benthic disturbance and can resolve intermediate changes in seafloor condition. In addition, we present a robust assessment of model performance which accounts for the effect of randomness in model creation. This work outlines a flexible framework for environmental assessments at aquaculture sites that is highly reproducible and free of taxonomy-assignment bias.
Highlights
Aquaculture is a significant global industry producing over 80 million t of food fish annually (FAO 2018)
Effluent and particulate matter from aquaculture operations released into the environment can drive significant benthic community changes, the detrimental effects of which have been widely studied, and extended aquaculture activities typically lead to changes in macrofaunal succession, decline in species diversity and in some cases, complete elimination of native infauna (Keeley et al 2014, Stoeck et al 2018)
This study examined a previously investigated microbiome dataset (NCBI BioProject PRJNA503189) containing Illumina-based sequencing data of the V6−V8 16S rRNA gene region performed on 108 flocculent matter samples collected below and near salmon aquaculture operations in Newfoundland, Canada (Verhoeven et al 2018)
Summary
Aquaculture is a significant global industry producing over 80 million t of food fish annually (FAO 2018). Over the last 3 decades, the industry has seen continued growth in production and contributes up to 46% of the total global fish output, including capture fisheries and aquaculture fisheries combined (FAO 2018). Concerns exist about the sustainability of aquaculture operations, in part due to the potential for negative environmental modification of associated ecosystems (Keeley et al 2014, Salvo et al.2017, Verhoeven et al 2018). Studies have shown that these effects are long-lasting, as they persist years after aquaculture operations have ceased (Verhoeven et al 2018)
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