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Pearl oyster bacterial community structure is governed by location and tissue-type, but vibrio species are shared among oyster tissues

Pearl oyster bacterial community structure is governed by location and tissue-type, but vibrio species are shared among oyster tissues
Pearl oyster bacterial community structure is governed by location and tissue-type, but vibrio species are shared among oyster tissues

Diseases of bivalves of aquacultural importance, including the valuable Australian silver-lipped pearl oyster (Pinctada maxima), have been increasing in frequency and severity. The bivalve microbiome is linked to health and disease dynamics, particularly in oysters, with putative pathogens within the Vibrio genus commonly implicated in oyster diseases. Previous studies have been biased toward the Pacific oyster because of its global dominance in oyster aquaculture, while much less is known about the microbiome of P. maxima. We sought to address this knowledge gap by characterizing the P. maxima bacterial community, and we hypothesized that bacterial community composition, and specifically the occurrence of Vibrio, will vary according to the sampled microenvironment. We also predicted that the inside shell swab bacterial composition could represent a source of microbial spillover biofilm into the solid pearl oyster tissues, thus providing a useful predictive sampling environment. We found that there was significant heterogeneity in bacterial composition between different pearl oyster tissues, which is consistent with patterns reported in other bivalve species and supports the hypothesis that each tissue type represents a unique microenvironment for bacterial colonization. We suggest that, based on the strong effect of tissue-type on the pearl oyster bacterial community, future studies should apply caution when attempting to compare microbial patterns from different locations, and when searching for disease agents. The lack of association with water at each farm also supported the unique nature of the microbial communities in oyster tissues. In contrast to the whole bacterial community, there was no significant difference in the Vibrio community among tissue types nor location. These results suggest that Vibrio species are shared among different pearl oyster tissues. In particular, the similarity between the haemolymph, inside shell and solid tissues, suggests that the haemolymph and inside shell environment is a source of microbial spillover into the oyster tissues, and a potentially useful tool for non-destructive routine disease testing and early warning surveillance. These data provide important foundational information for future studies identifying the factors that drive microbial assembly in a valuable aquaculture species.

bacterial communities, haemolymph, hsp60, pearl oyster (Pinctada maxima), tissue-type, Vibrio
1664-302X
King, William L.
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Kaestli, Mirjam
a33aa5e5-9574-47d6-8808-1b599da330c5
Siboni, Nachshon
cd5ba51e-896e-4b3f-be74-ab136fd96675
Padovan, Anna
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Christian, Keith
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Mills, David
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Seymour, Justin
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Gibb, Karen
b2ce10d9-2774-4d7e-bcec-94a5a1d9d9b3
King, William L.
0bd4328a-34ba-4b9a-bf4e-1442c18c43fc
Kaestli, Mirjam
a33aa5e5-9574-47d6-8808-1b599da330c5
Siboni, Nachshon
cd5ba51e-896e-4b3f-be74-ab136fd96675
Padovan, Anna
b687158a-97d0-4260-842a-cba8d14ffcdd
Christian, Keith
53367b29-3849-4c86-a22c-5be57d3e1da2
Mills, David
4e208bb6-2d47-49af-888b-057b99b19d87
Seymour, Justin
9b8a8df1-b392-4a9b-a513-54ea4c7172c7
Gibb, Karen
b2ce10d9-2774-4d7e-bcec-94a5a1d9d9b3

King, William L., Kaestli, Mirjam, Siboni, Nachshon, Padovan, Anna, Christian, Keith, Mills, David, Seymour, Justin and Gibb, Karen (2021) Pearl oyster bacterial community structure is governed by location and tissue-type, but vibrio species are shared among oyster tissues. Frontiers in Microbiology, 12, [723649]. (doi:10.3389/fmicb.2021.723649).

Record type: Article

Abstract

Diseases of bivalves of aquacultural importance, including the valuable Australian silver-lipped pearl oyster (Pinctada maxima), have been increasing in frequency and severity. The bivalve microbiome is linked to health and disease dynamics, particularly in oysters, with putative pathogens within the Vibrio genus commonly implicated in oyster diseases. Previous studies have been biased toward the Pacific oyster because of its global dominance in oyster aquaculture, while much less is known about the microbiome of P. maxima. We sought to address this knowledge gap by characterizing the P. maxima bacterial community, and we hypothesized that bacterial community composition, and specifically the occurrence of Vibrio, will vary according to the sampled microenvironment. We also predicted that the inside shell swab bacterial composition could represent a source of microbial spillover biofilm into the solid pearl oyster tissues, thus providing a useful predictive sampling environment. We found that there was significant heterogeneity in bacterial composition between different pearl oyster tissues, which is consistent with patterns reported in other bivalve species and supports the hypothesis that each tissue type represents a unique microenvironment for bacterial colonization. We suggest that, based on the strong effect of tissue-type on the pearl oyster bacterial community, future studies should apply caution when attempting to compare microbial patterns from different locations, and when searching for disease agents. The lack of association with water at each farm also supported the unique nature of the microbial communities in oyster tissues. In contrast to the whole bacterial community, there was no significant difference in the Vibrio community among tissue types nor location. These results suggest that Vibrio species are shared among different pearl oyster tissues. In particular, the similarity between the haemolymph, inside shell and solid tissues, suggests that the haemolymph and inside shell environment is a source of microbial spillover into the oyster tissues, and a potentially useful tool for non-destructive routine disease testing and early warning surveillance. These data provide important foundational information for future studies identifying the factors that drive microbial assembly in a valuable aquaculture species.

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More information

Published date: 9 August 2021
Additional Information: Funding Information: This research was supported by a Charles Darwin University internal grant, a Paspaley Pearls Group small grant and an Australian Research Council Linkage grant (LP 160101795) to JS. Publisher Copyright: © Copyright © 2021 King, Kaestli, Siboni, Padovan, Christian, Mills, Seymour and Gibb.
Keywords: bacterial communities, haemolymph, hsp60, pearl oyster (Pinctada maxima), tissue-type, Vibrio

Identifiers

Local EPrints ID: 486644
URI: http://eprints.soton.ac.uk/id/eprint/486644
ISSN: 1664-302X
PURE UUID: e516b102-4a15-4f31-b36e-96e35d9105c3
ORCID for William L. King: ORCID iD orcid.org/0000-0001-7272-8242

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Date deposited: 30 Jan 2024 17:53
Last modified: 18 Mar 2024 04:18

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Contributors

Author: William L. King ORCID iD
Author: Mirjam Kaestli
Author: Nachshon Siboni
Author: Anna Padovan
Author: Keith Christian
Author: David Mills
Author: Justin Seymour
Author: Karen Gibb

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