Abstract
One of the challenges in oceanography is to understand the influence of environmental factors on the abundances of prokaryotes and viruses. Generally, conventional statistical methods resolve trends well, but more complex relationships are difficult to explore. In such cases, Artificial Neural Networks (ANNs) offer an alternative way for data analysis. Here, we developed ANN-based models of prokaryotic and viral abundances in the Arctic Ocean. The models were used to identify the best predictors for prokaryotic and viral abundances including cytometrically-distinguishable populations of prokaryotes (high and low nucleic acid cells) and viruses (high- and low-fluorescent viruses) among salinity, temperature, depth, day length, and the concentration of Chlorophyll-a. The best performing ANNs to model the abundances of high and low nucleic acid cells used temperature and Chl-a as input parameters, while the abundances of high- and low-fluorescent viruses used depth, Chl-a, and day length as input parameters. Decreasing viral abundance with increasing depth and decreasing system productivity was captured well by the ANNs. Despite identifying the same predictors for the two populations of prokaryotes and viruses, respectively, the structure of the best performing ANNs differed between high and low nucleic acid cells and between high- and low-fluorescent viruses. Also, the two prokaryotic and viral groups responded differently to changes in the predictor parameters; hence, the cytometric distinction between these populations is ecologically relevant. The models imply that temperature is the main factor explaining most of the variation in the abundances of high nucleic acid cells and total prokaryotes and that the mechanisms governing the reaction to changes in the environment are distinctly different among the prokaryotic and viral populations.
Highlights
The Arctic Ocean is characterized by environmental extremes and is subject to large seasonal differences in ice cover, availability of sunlight, and river discharge that collectively set the pace for marine life in the area
We focus on differences between the seasonal and spatial data that are relevant for the modeling approach
Summary and conclusions The data in Payet and Suttle [20] detailed seasonal and spatial changes in the abundances of prokaryotes and viruses in the Arctic Ocean in the context of environmental data. Based on these data we demonstrated that it is possible to model the temporal development of the abundances of prokaryotes and viruses in the Arctic Ocean using Artificial Neural Networks (ANNs) and that these models are superior to Stepwise multiple linear regression (SMLR) models
Summary
The Arctic Ocean is characterized by environmental extremes and is subject to large seasonal differences in ice cover, availability of sunlight, and river discharge that collectively set the pace for marine life in the area. This polar region is influenced by the input of particles and nutrients due to coastal run-off and the discharge from large rivers. The signs of climate change in the Arctic Ocean include rising temperatures, increasing precipitation, and river discharge coupled with decreasing snow and ice cover [4,5,6]. These environmental changes have already had detectable effects on arctic organisms [7,8]
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