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Auteurs principaux: Ma, Xiao, Johnson, Kevin B, Li, Chaolun
Format: Artículo científico
Langue:en
Publié: Environmental science & technology 2026
Sujets:
Accès en ligne:https://pubmed.ncbi.nlm.nih.gov/41738442/
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author Ma, Xiao
Johnson, Kevin B
Li, Chaolun
author_facet Ma, Xiao
Johnson, Kevin B
Li, Chaolun
Ma, Xiao
Johnson, Kevin B
Li, Chaolun
collection PubMed - marine biology
contents Copepod Grazing and Prokaryotic Decomposition Amplify the Effect of Diatom-Dinoflagellate Regime Change on Biological Carbon Pump Efficiency. Ma, Xiao Johnson, Kevin B Li, Chaolun Animals Copepoda Diatoms Dinoflagellida Carbon Phytoplankton Copepod fecal pellets (FPs) are an important but highly variable component of the global Biological Carbon Pump (BCP). This study decoupled and quantified how copepod grazing and prokaryotic activities affect BCP efficiency under different phytoplankton dietary regimes. With a diet of diatoms, copepod FP production rates double, FP sinking rates triple, and FP decomposition rates are significantly lower relative to those with dinoflagellate diets. When dinoflagellates are the primary producers, inefficient grazing and enhanced prokaryotic activity synergistically decrease the efficiency of FP exports to the deep ocean. This finding confirms previous observations. Opportunistic particle-attached (PA) prokaryotes are crucial for FP decomposition. Metagenomic analyses revealed that CAZymes and lysosomal enzyme abundances highly correlated with FP decomposition rates, representing important bioindicators of FP decomposition. These functional enzymes targeting phytoplankton- and copepod-intestine-derived macromolecules from the PA prokaryotic communities were key to FP decomposition. Genomic properties of the Planctomycetota revealed that strong motile ability, detoxification systems, and macromolecule degradation enzymes enabled the success of these opportunistic PA prokaryotes. Elevated temperatures amplified FP decomposition rates by enhancing enzyme abundances and especially accelerated the decomposition of FPs composed of dinoflagellates. This reduced BCP efficiency, as rapidly recycled organic materials remain in surface waters. Our findings highlight the synergistic biological activities amplifying the effects of phytoplankton composition changes on BCP efficiency. This underscores the importance of considering grazing regimes in combination with microbial dynamics in assessing ocean carbon cycling.
format Artículo científico
id pubmed_41738442
institution PubMed
language en
publishDate 2026
publisher Environmental science & technology
record_format pubmed
spellingShingle Copepod Grazing and Prokaryotic Decomposition Amplify the Effect of Diatom-Dinoflagellate Regime Change on Biological Carbon Pump Efficiency.
Ma, Xiao
Johnson, Kevin B
Li, Chaolun
Animals
Copepoda
Diatoms
Dinoflagellida
Carbon
Phytoplankton
Copepod Grazing and Prokaryotic Decomposition Amplify the Effect of Diatom-Dinoflagellate Regime Change on Biological Carbon Pump Efficiency. Ma, Xiao Johnson, Kevin B Li, Chaolun Animals Copepoda Diatoms Dinoflagellida Carbon Phytoplankton Copepod fecal pellets (FPs) are an important but highly variable component of the global Biological Carbon Pump (BCP). This study decoupled and quantified how copepod grazing and prokaryotic activities affect BCP efficiency under different phytoplankton dietary regimes. With a diet of diatoms, copepod FP production rates double, FP sinking rates triple, and FP decomposition rates are significantly lower relative to those with dinoflagellate diets. When dinoflagellates are the primary producers, inefficient grazing and enhanced prokaryotic activity synergistically decrease the efficiency of FP exports to the deep ocean. This finding confirms previous observations. Opportunistic particle-attached (PA) prokaryotes are crucial for FP decomposition. Metagenomic analyses revealed that CAZymes and lysosomal enzyme abundances highly correlated with FP decomposition rates, representing important bioindicators of FP decomposition. These functional enzymes targeting phytoplankton- and copepod-intestine-derived macromolecules from the PA prokaryotic communities were key to FP decomposition. Genomic properties of the Planctomycetota revealed that strong motile ability, detoxification systems, and macromolecule degradation enzymes enabled the success of these opportunistic PA prokaryotes. Elevated temperatures amplified FP decomposition rates by enhancing enzyme abundances and especially accelerated the decomposition of FPs composed of dinoflagellates. This reduced BCP efficiency, as rapidly recycled organic materials remain in surface waters. Our findings highlight the synergistic biological activities amplifying the effects of phytoplankton composition changes on BCP efficiency. This underscores the importance of considering grazing regimes in combination with microbial dynamics in assessing ocean carbon cycling.
title Copepod Grazing and Prokaryotic Decomposition Amplify the Effect of Diatom-Dinoflagellate Regime Change on Biological Carbon Pump Efficiency.
topic Animals
Copepoda
Diatoms
Dinoflagellida
Carbon
Phytoplankton
url https://pubmed.ncbi.nlm.nih.gov/41738442/