Additional file 1 of Differential response of digesta- and mucosa-associated intestinal microbiota to dietary insect meal during the seawater phase of Atlantic salmon

Additional file 1: Figure S1. Quantification of bacterial 16S rRNA gene in different sample types using qPCR. Since the Cq values of most mucosa-associated samples were out of the linear range of the standard curve, the Cq value was used as a proxy of 16S rRNA gene quantity which is reliable for the...

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Main Authors: Li, Yanxian, Bruni, Leonardo, Jaramillo-Torres, Alexander, Gajardo, Karina, Kortner, Trond M., Krogdahl, Åshild
Format: Text
Language:unknown
Published: figshare 2021
Subjects:
Microbiology
FOS Biological sciences
Genetics
Atlantic salmon
Online Access:https://dx.doi.org/10.6084/m9.figshare.13545373.v1
https://springernature.figshare.com/articles/journal_contribution/Additional_file_1_of_Differential_response_of_digesta-_and_mucosa-associated_intestinal_microbiota_to_dietary_insect_meal_during_the_seawater_phase_of_Atlantic_salmon/13545373/1
id ftdatacite:10.6084/m9.figshare.13545373.v1
record_format openpolar
institution Open Polar
collection DataCite Metadata Store (German National Library of Science and Technology)
op_collection_id ftdatacite
language unknown
topic Microbiology
FOS Biological sciences
Genetics
spellingShingle Microbiology
FOS Biological sciences
Genetics
Li, Yanxian
Bruni, Leonardo
Jaramillo-Torres, Alexander
Gajardo, Karina
Kortner, Trond M.
Krogdahl, Åshild
Additional file 1 of Differential response of digesta- and mucosa-associated intestinal microbiota to dietary insect meal during the seawater phase of Atlantic salmon
topic_facet Microbiology
FOS Biological sciences
Genetics
description Additional file 1: Figure S1. Quantification of bacterial 16S rRNA gene in different sample types using qPCR. Since the Cq values of most mucosa-associated samples were out of the linear range of the standard curve, the Cq value was used as a proxy of 16S rRNA gene quantity which is reliable for the screening of contaminant sequences. Data are presented as mean ± 1 standard deviation overlaying the raw data points. Abbreviations: REF, reference diet; IM, insect meal diet; DID, distal intestine digesta; DIM, distal intestine mucosa. Figure S2. Taxonomic profile of the mock (A) and contaminating features in the negative controls (B). The lowest level of taxonomic ranks was displayed for each taxon. EB, extraction blank; LB, library blank. Figure S3. Microbial clades showing significant associations with sample origin. p__, phylum; o__, order; f__, family; FDR, false discovery rate; N.not.zero, number of non-zero observations; REF, reference diet; IM, insect meal diet. Figure S4. Microbial clades showing significant associations with diet. p__, phylum; o__, order; f__, family; FDR, false discovery rate; N.not.zero, number of non-zero observations; REF, reference diet; IM, insect meal diet. Figure S5. Microbial clades showing significant associations with histological scores on lamina propria cellularity in the distal intestine. p__, phylum; f__, family; FDR, false discovery rate; N.not.zero, number of non-zero observations. Figure S6. Microbial clades showing significant associations with distal intestine somatic index (DISI). FDR, false discovery rate; N.not.zero, number of non-zero observations. Figure S7. Microbial clades showing significant associations with immune gene expressions in the distal intestine. Since the expression levels of immune genes were highly correlated, we ran a principle component analysis (PCA) and used the first principle component (PC1) for the association testing to avoid multicollinearity and reduce the number of association testing. Note that the expression levels of immune genes decrease as the PC1 increases from left to right. Hence, a positive correlation coefficient denotes a negative association between the microbial clade and immune gene expressions, and vice versa. f__, family; FDR, false discovery rate; N.not.zero, number of non-zero observations. Figure S8. Microbial clades showing significant associations with expressions of barrier function related genes in the distal intestine. Since the expression levels of barrier function related genes were highly correlated, we ran a principle component analysis (PCA) and used the first principle component (PC1) for the association testing to avoid multicollinearity and reduce the number of association testing. Note that the expression levels of barrier function related genes decrease as the PC1 increases from left to right. Hence, a positive correlation coefficient denotes a negative association between the microbial clade and barrier function related gene expressions, and vice versa. f__, family; FDR, false discovery rate; N.not.zero, number of non-zero observations. Figure S9. Rarefaction curves based on Observed ASVs for the different sample types. The rarefaction analysis showed that mucosa samples (REF-DIM, IM-DIM) reached the saturation phase at a subsampling depth of 2000 sequences whereas digesta samples (REF-DID, IM-DID) reached the saturation phase at a subsampling depth of 9500 sequences. To preserve a maximum number of samples for the downstream data analysis, we rarefied the ASV table to 2047 sequences per sample which left out 2 samples. To ensure that the subsampling depth of 2047 sequences per sample produced reliable comparisons of microbial communities, we computed compositionality-aware distance matrices, the Aitchison distance and PHILR transformed Euclidean distance, which do not require rarefying and use all the sequences in the samples.
format Text
author Li, Yanxian
Bruni, Leonardo
Jaramillo-Torres, Alexander
Gajardo, Karina
Kortner, Trond M.
Krogdahl, Åshild
author_facet Li, Yanxian
Bruni, Leonardo
Jaramillo-Torres, Alexander
Gajardo, Karina
Kortner, Trond M.
Krogdahl, Åshild
author_sort Li, Yanxian
title Additional file 1 of Differential response of digesta- and mucosa-associated intestinal microbiota to dietary insect meal during the seawater phase of Atlantic salmon
title_short Additional file 1 of Differential response of digesta- and mucosa-associated intestinal microbiota to dietary insect meal during the seawater phase of Atlantic salmon
title_full Additional file 1 of Differential response of digesta- and mucosa-associated intestinal microbiota to dietary insect meal during the seawater phase of Atlantic salmon
title_fullStr Additional file 1 of Differential response of digesta- and mucosa-associated intestinal microbiota to dietary insect meal during the seawater phase of Atlantic salmon
title_full_unstemmed Additional file 1 of Differential response of digesta- and mucosa-associated intestinal microbiota to dietary insect meal during the seawater phase of Atlantic salmon
title_sort additional file 1 of differential response of digesta- and mucosa-associated intestinal microbiota to dietary insect meal during the seawater phase of atlantic salmon
publisher figshare
publishDate 2021
url https://dx.doi.org/10.6084/m9.figshare.13545373.v1
https://springernature.figshare.com/articles/journal_contribution/Additional_file_1_of_Differential_response_of_digesta-_and_mucosa-associated_intestinal_microbiota_to_dietary_insect_meal_during_the_seawater_phase_of_Atlantic_salmon/13545373/1
genre Atlantic salmon
genre_facet Atlantic salmon
op_relation https://dx.doi.org/10.1186/s42523-020-00071-3
https://dx.doi.org/10.6084/m9.figshare.13545373
op_rights Creative Commons Attribution 4.0 International
https://creativecommons.org/licenses/by/4.0/legalcode
cc-by-4.0
op_rightsnorm CC-BY
op_doi https://doi.org/10.6084/m9.figshare.13545373.v1
https://doi.org/10.1186/s42523-020-00071-3
https://doi.org/10.6084/m9.figshare.13545373
_version_ 1766363629927530496
spelling ftdatacite:10.6084/m9.figshare.13545373.v1 2023-05-15T15:33:09+02:00 Additional file 1 of Differential response of digesta- and mucosa-associated intestinal microbiota to dietary insect meal during the seawater phase of Atlantic salmon Li, Yanxian Bruni, Leonardo Jaramillo-Torres, Alexander Gajardo, Karina Kortner, Trond M. Krogdahl, Åshild 2021 https://dx.doi.org/10.6084/m9.figshare.13545373.v1 https://springernature.figshare.com/articles/journal_contribution/Additional_file_1_of_Differential_response_of_digesta-_and_mucosa-associated_intestinal_microbiota_to_dietary_insect_meal_during_the_seawater_phase_of_Atlantic_salmon/13545373/1 unknown figshare https://dx.doi.org/10.1186/s42523-020-00071-3 https://dx.doi.org/10.6084/m9.figshare.13545373 Creative Commons Attribution 4.0 International https://creativecommons.org/licenses/by/4.0/legalcode cc-by-4.0 CC-BY Microbiology FOS Biological sciences Genetics Text article-journal Journal contribution ScholarlyArticle 2021 ftdatacite https://doi.org/10.6084/m9.figshare.13545373.v1 https://doi.org/10.1186/s42523-020-00071-3 https://doi.org/10.6084/m9.figshare.13545373 2021-11-05T12:55:41Z Additional file 1: Figure S1. Quantification of bacterial 16S rRNA gene in different sample types using qPCR. Since the Cq values of most mucosa-associated samples were out of the linear range of the standard curve, the Cq value was used as a proxy of 16S rRNA gene quantity which is reliable for the screening of contaminant sequences. Data are presented as mean ± 1 standard deviation overlaying the raw data points. Abbreviations: REF, reference diet; IM, insect meal diet; DID, distal intestine digesta; DIM, distal intestine mucosa. Figure S2. Taxonomic profile of the mock (A) and contaminating features in the negative controls (B). The lowest level of taxonomic ranks was displayed for each taxon. EB, extraction blank; LB, library blank. Figure S3. Microbial clades showing significant associations with sample origin. p__, phylum; o__, order; f__, family; FDR, false discovery rate; N.not.zero, number of non-zero observations; REF, reference diet; IM, insect meal diet. Figure S4. Microbial clades showing significant associations with diet. p__, phylum; o__, order; f__, family; FDR, false discovery rate; N.not.zero, number of non-zero observations; REF, reference diet; IM, insect meal diet. Figure S5. Microbial clades showing significant associations with histological scores on lamina propria cellularity in the distal intestine. p__, phylum; f__, family; FDR, false discovery rate; N.not.zero, number of non-zero observations. Figure S6. Microbial clades showing significant associations with distal intestine somatic index (DISI). FDR, false discovery rate; N.not.zero, number of non-zero observations. Figure S7. Microbial clades showing significant associations with immune gene expressions in the distal intestine. Since the expression levels of immune genes were highly correlated, we ran a principle component analysis (PCA) and used the first principle component (PC1) for the association testing to avoid multicollinearity and reduce the number of association testing. Note that the expression levels of immune genes decrease as the PC1 increases from left to right. Hence, a positive correlation coefficient denotes a negative association between the microbial clade and immune gene expressions, and vice versa. f__, family; FDR, false discovery rate; N.not.zero, number of non-zero observations. Figure S8. Microbial clades showing significant associations with expressions of barrier function related genes in the distal intestine. Since the expression levels of barrier function related genes were highly correlated, we ran a principle component analysis (PCA) and used the first principle component (PC1) for the association testing to avoid multicollinearity and reduce the number of association testing. Note that the expression levels of barrier function related genes decrease as the PC1 increases from left to right. Hence, a positive correlation coefficient denotes a negative association between the microbial clade and barrier function related gene expressions, and vice versa. f__, family; FDR, false discovery rate; N.not.zero, number of non-zero observations. Figure S9. Rarefaction curves based on Observed ASVs for the different sample types. The rarefaction analysis showed that mucosa samples (REF-DIM, IM-DIM) reached the saturation phase at a subsampling depth of 2000 sequences whereas digesta samples (REF-DID, IM-DID) reached the saturation phase at a subsampling depth of 9500 sequences. To preserve a maximum number of samples for the downstream data analysis, we rarefied the ASV table to 2047 sequences per sample which left out 2 samples. To ensure that the subsampling depth of 2047 sequences per sample produced reliable comparisons of microbial communities, we computed compositionality-aware distance matrices, the Aitchison distance and PHILR transformed Euclidean distance, which do not require rarefying and use all the sequences in the samples. Text Atlantic salmon DataCite Metadata Store (German National Library of Science and Technology)

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