AI Article Synopsis
- This analysis focuses on marine protistan plankton that acquire phototrophy, highlighting their widespread presence and varying biogeographical patterns among different functional groups.
- Non-constitutive mixotrophs (NCMs), which obtain their photosynthetic abilities through ingestion of prey or endosymbiotic relationships, make up a significant portion (40-60%) of what was previously thought to be non-phototrophic microzooplankton.
- The study reveals distinct seasonal and spatial distributions for specialist versus generalist NCMs, suggesting a need to reassess marine food web models and the role of mixotrophs in ocean ecosystems.
Article Abstract
This first comprehensive analysis of the global biogeography of marine protistan plankton with acquired phototrophy shows these mixotrophic organisms to be ubiquitous and abundant; however, their biogeography differs markedly between different functional groups. These mixotrophs, lacking a constitutive capacity for photosynthesis (i.e. non-constitutive mixotrophs, NCMs), acquire their phototrophic potential through either integration of prey-plastids or through endosymbiotic associations with photosynthetic microbes. Analysis of field data reveals that 40-60% of plankton traditionally labelled as (non-phototrophic) microzooplankton are actually NCMs, employing acquired phototrophy in addition to phagotrophy. Specialist NCMs acquire chloroplasts or endosymbionts from specific prey, while generalist NCMs obtain chloroplasts from a variety of prey. These contrasting functional types of NCMs exhibit distinct seasonal and spatial global distribution patterns. Mixotrophs reliant on 'stolen' chloroplasts, controlled by prey diversity and abundance, dominate in high-biomass areas. Mixotrophs harbouring intact symbionts are present in all waters and dominate particularly in oligotrophic open ocean systems. The contrasting temporal and spatial patterns of distribution of different mixotroph functional types across the oceanic provinces, as revealed in this study, challenges traditional interpretations of marine food web structures. Mixotrophs with acquired phototrophy (NCMs) warrant greater recognition in marine research.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC5563798 | PMC |
| http://dx.doi.org/10.1098/rspb.2017.0664 | DOI Listing |
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