Data_Sheet_1_Dietary Exposure of Pacific Oyster (Crassostrea gigas) Larvae to Compromised Microalgae Results in Impaired Fitness and Microbiome Shift.docx

The Pacific oyster Crassostrea gigas is the world’s most cultivated oyster and seed supply is heavily reliant on hatchery production where recurring mass mortality events are a major constraint. Outbreaks of bacterial infection via microalgal feed are frequently implicated in these mortalities. This...

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Main Authors: Julien Vignier (11323257), Olivier Laroche (4568134), Anne Rolton (11323260), Pandora Wadsworth (11323263), Karthiga Kumanan (11323266), Branwen Trochel (11323269), Xavier Pochon (160365), Nick King (11323272)
Format: Dataset
Language:unknown
Published: 2021
Subjects:
Microbiology
Microbial Genetics
Microbial Ecology
Mycology
oyster hatchery
larvae
Crassostrea gigas
microalgae
fitness
microbiome
16S rRNA gene sequencing
Pacific
Pacific oyster
Online Access:https://doi.org/10.3389/fmicb.2021.706214.s001
id ftsmithonian:oai:figshare.com:article/16418274
record_format openpolar
spelling ftsmithonian:oai:figshare.com:article/16418274 2023-05-15T15:58:03+02:00 Data_Sheet_1_Dietary Exposure of Pacific Oyster (Crassostrea gigas) Larvae to Compromised Microalgae Results in Impaired Fitness and Microbiome Shift.docx Julien Vignier (11323257) Olivier Laroche (4568134) Anne Rolton (11323260) Pandora Wadsworth (11323263) Karthiga Kumanan (11323266) Branwen Trochel (11323269) Xavier Pochon (160365) Nick King (11323272) 2021-08-24T05:06:57Z https://doi.org/10.3389/fmicb.2021.706214.s001 unknown https://figshare.com/articles/dataset/Data_Sheet_1_Dietary_Exposure_of_Pacific_Oyster_Crassostrea_gigas_Larvae_to_Compromised_Microalgae_Results_in_Impaired_Fitness_and_Microbiome_Shift_docx/16418274 doi:10.3389/fmicb.2021.706214.s001 CC BY 4.0 CC-BY Microbiology Microbial Genetics Microbial Ecology Mycology oyster hatchery larvae Crassostrea gigas microalgae fitness microbiome 16S rRNA gene sequencing Dataset 2021 ftsmithonian https://doi.org/10.3389/fmicb.2021.706214.s001 2021-12-20T03:43:30Z The Pacific oyster Crassostrea gigas is the world’s most cultivated oyster and seed supply is heavily reliant on hatchery production where recurring mass mortality events are a major constraint. Outbreaks of bacterial infection via microalgal feed are frequently implicated in these mortalities. This study assessed the effects of feeding compromised microalgae to developing oyster larvae. Intentionally ‘stressed’ (high pH) or non-stressed microalgae were fed to 11 day-old oyster larvae at two feeding rations for 96 h, followed by a recovery period. Biological endpoints of larval performance were measured following the 96 h exposure and subsequent recovery. Bacterial communities associated with the microalgae feed, rearing seawater, and the oyster larvae, were characterized and correlated with effects on oyster fitness parameters. Feeding stressed algae to oyster larvae for 96 h increased the occurrence of deformities (>70% vs. 20% in control), reduced feeding and swimming ability, and slowed development. Following the recovery period, fewer larvae reached pediveliger stage (2.7% vs. 36% in control) and became spat (1.5% vs. 6.6% in control). The quantity of stressed algae supplied to oyster larvae also influenced overall larval performance, with high feeding rations generally causing greater impairment than low rations. Bacterial profiling using 16S rRNA showed that most bacterial families characterized in larval tissue were also present in larval rearing seawater and in the microalgae feed (98%). The rearing seawater showed the highest bacterial richness compared to the larval and the microalgal compartments, regardless of feeding regime. In larval tissue, bacterial richness was highest in stressed and high-feed treatments, and negatively correlated with larval fitness parameters. These results suggest significant dysbiosis induced by compromised feed and/or increased feed ration. Several bacterial genera (e.g., Halomonas, Marinomonas) were strongly associated with impaired larval performance while the presence of genera in larvae including Vibrio was closely associated with overfeeding. Our research demonstrated that metabarcoding can be effectively used to identify microbiota features associated with larval fitness. Dataset Crassostrea gigas Pacific oyster Unknown Pacific
institution Open Polar
collection Unknown
op_collection_id ftsmithonian
language unknown
topic Microbiology
Microbial Genetics
Microbial Ecology
Mycology
oyster hatchery
larvae
Crassostrea gigas
microalgae
fitness
microbiome
16S rRNA gene sequencing
spellingShingle Microbiology
Microbial Genetics
Microbial Ecology
Mycology
oyster hatchery
larvae
Crassostrea gigas
microalgae
fitness
microbiome
16S rRNA gene sequencing
Julien Vignier (11323257)
Olivier Laroche (4568134)
Anne Rolton (11323260)
Pandora Wadsworth (11323263)
Karthiga Kumanan (11323266)
Branwen Trochel (11323269)
Xavier Pochon (160365)
Nick King (11323272)
Data_Sheet_1_Dietary Exposure of Pacific Oyster (Crassostrea gigas) Larvae to Compromised Microalgae Results in Impaired Fitness and Microbiome Shift.docx
topic_facet Microbiology
Microbial Genetics
Microbial Ecology
Mycology
oyster hatchery
larvae
Crassostrea gigas
microalgae
fitness
microbiome
16S rRNA gene sequencing
description The Pacific oyster Crassostrea gigas is the world’s most cultivated oyster and seed supply is heavily reliant on hatchery production where recurring mass mortality events are a major constraint. Outbreaks of bacterial infection via microalgal feed are frequently implicated in these mortalities. This study assessed the effects of feeding compromised microalgae to developing oyster larvae. Intentionally ‘stressed’ (high pH) or non-stressed microalgae were fed to 11 day-old oyster larvae at two feeding rations for 96 h, followed by a recovery period. Biological endpoints of larval performance were measured following the 96 h exposure and subsequent recovery. Bacterial communities associated with the microalgae feed, rearing seawater, and the oyster larvae, were characterized and correlated with effects on oyster fitness parameters. Feeding stressed algae to oyster larvae for 96 h increased the occurrence of deformities (>70% vs. 20% in control), reduced feeding and swimming ability, and slowed development. Following the recovery period, fewer larvae reached pediveliger stage (2.7% vs. 36% in control) and became spat (1.5% vs. 6.6% in control). The quantity of stressed algae supplied to oyster larvae also influenced overall larval performance, with high feeding rations generally causing greater impairment than low rations. Bacterial profiling using 16S rRNA showed that most bacterial families characterized in larval tissue were also present in larval rearing seawater and in the microalgae feed (98%). The rearing seawater showed the highest bacterial richness compared to the larval and the microalgal compartments, regardless of feeding regime. In larval tissue, bacterial richness was highest in stressed and high-feed treatments, and negatively correlated with larval fitness parameters. These results suggest significant dysbiosis induced by compromised feed and/or increased feed ration. Several bacterial genera (e.g., Halomonas, Marinomonas) were strongly associated with impaired larval performance while the presence of genera in larvae including Vibrio was closely associated with overfeeding. Our research demonstrated that metabarcoding can be effectively used to identify microbiota features associated with larval fitness.
format Dataset
author Julien Vignier (11323257)
Olivier Laroche (4568134)
Anne Rolton (11323260)
Pandora Wadsworth (11323263)
Karthiga Kumanan (11323266)
Branwen Trochel (11323269)
Xavier Pochon (160365)
Nick King (11323272)
author_facet Julien Vignier (11323257)
Olivier Laroche (4568134)
Anne Rolton (11323260)
Pandora Wadsworth (11323263)
Karthiga Kumanan (11323266)
Branwen Trochel (11323269)
Xavier Pochon (160365)
Nick King (11323272)
author_sort Julien Vignier (11323257)
title Data_Sheet_1_Dietary Exposure of Pacific Oyster (Crassostrea gigas) Larvae to Compromised Microalgae Results in Impaired Fitness and Microbiome Shift.docx
title_short Data_Sheet_1_Dietary Exposure of Pacific Oyster (Crassostrea gigas) Larvae to Compromised Microalgae Results in Impaired Fitness and Microbiome Shift.docx
title_full Data_Sheet_1_Dietary Exposure of Pacific Oyster (Crassostrea gigas) Larvae to Compromised Microalgae Results in Impaired Fitness and Microbiome Shift.docx
title_fullStr Data_Sheet_1_Dietary Exposure of Pacific Oyster (Crassostrea gigas) Larvae to Compromised Microalgae Results in Impaired Fitness and Microbiome Shift.docx
title_full_unstemmed Data_Sheet_1_Dietary Exposure of Pacific Oyster (Crassostrea gigas) Larvae to Compromised Microalgae Results in Impaired Fitness and Microbiome Shift.docx
title_sort data_sheet_1_dietary exposure of pacific oyster (crassostrea gigas) larvae to compromised microalgae results in impaired fitness and microbiome shift.docx
publishDate 2021
url https://doi.org/10.3389/fmicb.2021.706214.s001
geographic Pacific
geographic_facet Pacific
genre Crassostrea gigas
Pacific oyster
genre_facet Crassostrea gigas
Pacific oyster
op_relation https://figshare.com/articles/dataset/Data_Sheet_1_Dietary_Exposure_of_Pacific_Oyster_Crassostrea_gigas_Larvae_to_Compromised_Microalgae_Results_in_Impaired_Fitness_and_Microbiome_Shift_docx/16418274
doi:10.3389/fmicb.2021.706214.s001
op_rights CC BY 4.0
op_rightsnorm CC-BY
op_doi https://doi.org/10.3389/fmicb.2021.706214.s001
_version_ 1766393771061149696

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