Abstract
A significant proportion of phototrophic species are known to be mixotrophs: cells that obtain nutrients through a combination of photosynthesis and prey ingestion. Current methods to estimate mixotroph abundance in situ are known to be limited in their ability to help identify conditions that favor mixotrophs over strict autotrophs. For the first time, we combine microscopic analysis of phototrophic taxa with immunoprecipitated bromodeoxyuridine (BrdU)-labeled DNA amplicon sequencing to identify and quantify active and putative mixotrophs at 2 locations in a microtidal temperate estuary. We analyze these data to examine spatial and temporal variability of phytoplankton and mixotrophs. Microscopy-based phototrophic diversity and abundances reveal expected seasonal patterns for our 2 stations, with the start of growth in winter and highest abundances in summer. Diatoms tend to dominate at the site with less stratification, while dinoflagellates and euglenids are usually more prominent at the stratified station. The BrdU-based mixotroph identifications are translated to the microscopy identification and abundances to estimate the proportion of mixotrophs (cells >10 µm in size) at both sites. The average proportion of potential mixotrophs is higher at the station with higher stratification (51%) compared to the station with lower stratification (30%), and potential mixotrophs tend to be higher in summer, although we did not conduct BrdU experiments in any of the other seasons. Combining the identification of active mixotrophs through the uptake of BrdU-labeled bacteria with robust abundance measurements can expand our understanding of mixotrophs across systems.
Highlights
Phototrophic plankton form the base of most aquatic food webs, producing organic carbon that will be utilized by higher trophic levels
This study provides some of the first data on the proportion of potential mixotrophs within the phototrophic assemblage throughout the year in a temperate estuary
The environmental data we considered were water temperature, salinity, turbidity, ammonium, nitrate + nitrite (NOx), silicate, ortho-phosphate, dissolved inorganic nitrogen (DIN) and total nitrogen (TN) concentration, DIN: dissolved inorganic ortho-phosphate (DIP) ratio, and stratification index (0−1)
Summary
Phototrophic plankton form the base of most aquatic food webs, producing organic carbon that will be utilized by higher trophic levels. Schneider et al (2020) used microscopy-based taxonomic information from a long-term North Sea dataset to link the occurrence and abundance of potential mixotrophs with abiotic conditions (offshore versus estuarine). While this method of potential mixotroph identification provides the opportunity to reanalyze available microscopy samples and estimate the proportion of mixotrophs, it likely overestimates their abundance since species presence does not necessarily translate to mixotroph behavior
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