You Are What You Eat: A Genomic Analysis of the Gut Microbiome of Captive and Wild Paralarvae and Their Zooplankton Prey

Overview

Journal Front Physiol

Date 2017 Jun 17

PMID 28620315

Citations 10

Authors

Alvaro Roura

Stephen R Doyle

Manuel Nande

Jan M Strugnell

Affiliations

Soon will be listed here.

Abstract

The common octopus () is an attractive species for aquaculture, however, several challenges inhibit sustainable commercial production. Little is known about the early paralarval stages in the wild, including diet and intestinal microbiota, which likely play a significant role in development and vitality of this important life stage. High throughput sequencing was used to characterize the gastrointestinal microbiome of wild paralarvae collected from two different upwelling regions off the coast of North West Spain ( = 41) and Morocco ( = 35). These were compared to that of paralarvae reared with for up to 25 days in captivity ( = 29). In addition, the gastrointestinal microbiome of zooplankton prey (crabs, copepod and krill) was also analyzed to determine if the microbial communities present in wild paralarvae are derived from their diet. Paralarvae reared in captivity with showed a depletion of bacterial diversity, particularly after day 5, when almost half the bacterial species present on day 0 were lost and two bacterial families (Mycoplasmataceae and Vibrionaceae) dominated the microbial community. In contrast, bacterial diversity increased in wild paralarvae as they developed in the oceanic realm of both upwelling systems, likely due to the exposure of new bacterial communities via ingestion of a wide diversity of prey. Remarkably, the bacterial diversity of recently hatched paralarvae in captivity was similar to that of wild paralarvae and zooplankton, thus suggesting a marked effect of the diet in both the microbial community species diversity and evenness. This study provides a comprehensive overview of the bacterial communities inhabiting the gastrointestinal tract of paralarvae, and reveals new research lines to challenge the current bottlenecks preventing sustainable octopus aquaculture.

Citing Articles

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