Distribution, Associations and Role in the Biological Carbon Pump of Pyrosoma Atlanticum (Tunicata, Thaliacea) off Cabo Verde, NE Atlantic

Overview

Journal Sci Rep

Specialty Science

Date 2021 Apr 30

PMID 33927222

Citations 3

Authors

Vanessa I Stenvers

Helena Hauss

Karen J Osborn

Philipp Neitzel

Veronique Merten

Stella Scheer

Bruce H Robison

Rui Freitas

Henk Jan T Hoving

Affiliations

Soon will be listed here.

Abstract

Gelatinous zooplankton are increasingly acknowledged to contribute significantly to the carbon cycle worldwide, yet many taxa within this diverse group remain poorly studied. Here, we investigate the pelagic tunicate Pyrosoma atlanticum in the waters surrounding the Cabo Verde Archipelago. By using a combination of pelagic and benthic in situ observations, sampling, and molecular genetic analyses (barcoding, eDNA), we reveal that: P. atlanticum abundance is most likely driven by local island-induced productivity, that it substantially contributes to the organic carbon export flux and is part of a diverse range of biological interactions. Downward migrating pyrosomes actively transported an estimated 13% of their fecal pellets below the mixed layer, equaling a carbon flux of 1.96-64.55 mg C m day. We show that analysis of eDNA can detect pyrosome material beyond their migration range, suggesting that pyrosomes have ecological impacts below the upper water column. Moribund P. atlanticum colonies contributed an average of 15.09 ± 17.89 (s.d.) mg C m to the carbon flux reaching the island benthic slopes. Our pelagic in situ observations further show that P. atlanticum formed an abundant substrate in the water column (reaching up to 0.28 m substrate area per m), with animals using pyrosomes for settlement, as a shelter and/or a food source. In total, twelve taxa from four phyla were observed to interact with pyrosomes in the midwater and on the benthos.

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