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Auteurs principaux: Pauli, Nora-Charlotte, Metfies, Katja, Neuhaus, Stefan, Graeve, Martin, Cleary, Alison C, Iversen, Morten H, Meyer, Bettina
Format: Artículo científico
Langue:en
Publié: Molecular ecology resources 2025
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Accès en ligne:https://pubmed.ncbi.nlm.nih.gov/40823735/
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author Pauli, Nora-Charlotte
Metfies, Katja
Neuhaus, Stefan
Graeve, Martin
Cleary, Alison C
Iversen, Morten H
Meyer, Bettina
author_facet Pauli, Nora-Charlotte
Metfies, Katja
Neuhaus, Stefan
Graeve, Martin
Cleary, Alison C
Iversen, Morten H
Meyer, Bettina
Pauli, Nora-Charlotte
Metfies, Katja
Neuhaus, Stefan
Graeve, Martin
Cleary, Alison C
Iversen, Morten H
Meyer, Bettina
collection PubMed - marine biology
contents Refining Zooplankton Diet Composition Studies Over Short and Long Time Scales by Combining 18S Metabarcoding With Fatty Acid Analyses. Pauli, Nora-Charlotte Metfies, Katja Neuhaus, Stefan Graeve, Martin Cleary, Alison C Iversen, Morten H Meyer, Bettina Animals DNA Barcoding, Taxonomic Zooplankton RNA, Ribosomal, 18S Fatty Acids Euphausiacea Diet Antarctic Regions Understanding diet composition is essential for unravelling trophic interactions in aquatic ecosystems. DNA metabarcoding, utilising various variable regions of the 18S rRNA gene, is increasingly employed to investigate zooplankton diet composition. However, accurate results depend on rapid inactivation of digestive enzymes and DNA nucleases through proper sample processing and preservation. In this study, we compare the prey communities of Antarctic krill retrieved from the 18S variable regions V4 and V7 and assess how different processing treatments affect the detected prey composition of both krill and salps. Our findings highlight the critical importance of prompt sample processing for species with highly efficient digestive enzymes, such as krill, to preserve rapidly digested prey, including gelatinous plankton. Comparative analyses of the V4 and V7 regions revealed significantly different prey communities within the same krill samples, indicating that these regions may not be suitable for direct comparisons within or across studies. To complement molecular approaches, we also analyse fatty acids (FA) as trophic markers which provide insights into dietary habits over both short and long time scales. By comparing FA signals from stomach and tissue samples of the same krill and salp individuals, we identified significant differences in trophic markers representing different plankton groups. These findings emphasise the necessity of separating digestive tract from tissue to distinguish between short- and long-term diet signals. Furthermore, integrating FA analysis with metabarcoding offers valuable insights into zooplankton digestion efficiency across taxonomic levels. This combined approach enhances our understanding of zooplankton feeding ecology and trophic interactions in marine ecosystems.
format Artículo científico
id pubmed_40823735
institution PubMed
language en
publishDate 2025
publisher Molecular ecology resources
record_format pubmed
spellingShingle Refining Zooplankton Diet Composition Studies Over Short and Long Time Scales by Combining 18S Metabarcoding With Fatty Acid Analyses.
Pauli, Nora-Charlotte
Metfies, Katja
Neuhaus, Stefan
Graeve, Martin
Cleary, Alison C
Iversen, Morten H
Meyer, Bettina
Animals
DNA Barcoding, Taxonomic
Zooplankton
RNA, Ribosomal, 18S
Fatty Acids
Euphausiacea
Diet
Antarctic Regions
Refining Zooplankton Diet Composition Studies Over Short and Long Time Scales by Combining 18S Metabarcoding With Fatty Acid Analyses. Pauli, Nora-Charlotte Metfies, Katja Neuhaus, Stefan Graeve, Martin Cleary, Alison C Iversen, Morten H Meyer, Bettina Animals DNA Barcoding, Taxonomic Zooplankton RNA, Ribosomal, 18S Fatty Acids Euphausiacea Diet Antarctic Regions Understanding diet composition is essential for unravelling trophic interactions in aquatic ecosystems. DNA metabarcoding, utilising various variable regions of the 18S rRNA gene, is increasingly employed to investigate zooplankton diet composition. However, accurate results depend on rapid inactivation of digestive enzymes and DNA nucleases through proper sample processing and preservation. In this study, we compare the prey communities of Antarctic krill retrieved from the 18S variable regions V4 and V7 and assess how different processing treatments affect the detected prey composition of both krill and salps. Our findings highlight the critical importance of prompt sample processing for species with highly efficient digestive enzymes, such as krill, to preserve rapidly digested prey, including gelatinous plankton. Comparative analyses of the V4 and V7 regions revealed significantly different prey communities within the same krill samples, indicating that these regions may not be suitable for direct comparisons within or across studies. To complement molecular approaches, we also analyse fatty acids (FA) as trophic markers which provide insights into dietary habits over both short and long time scales. By comparing FA signals from stomach and tissue samples of the same krill and salp individuals, we identified significant differences in trophic markers representing different plankton groups. These findings emphasise the necessity of separating digestive tract from tissue to distinguish between short- and long-term diet signals. Furthermore, integrating FA analysis with metabarcoding offers valuable insights into zooplankton digestion efficiency across taxonomic levels. This combined approach enhances our understanding of zooplankton feeding ecology and trophic interactions in marine ecosystems.
title Refining Zooplankton Diet Composition Studies Over Short and Long Time Scales by Combining 18S Metabarcoding With Fatty Acid Analyses.
topic Animals
DNA Barcoding, Taxonomic
Zooplankton
RNA, Ribosomal, 18S
Fatty Acids
Euphausiacea
Diet
Antarctic Regions
url https://pubmed.ncbi.nlm.nih.gov/40823735/