Your search keyword '"selfish symbiont"' showing total 5 results

1. Corrigendum: Using Aiptasia as a Model to Study Metabolic Interactions in Cnidarian-Symbiodinium Symbioses

Author

Nils Rädecker, Jean-Baptiste Raina, Mathieu Pernice, Gabriela Perna, Paul Guagliardo, Matt R. Kilburn, Manuel Aranda, and Christian R. Voolstra

Subjects

metaorganism, holobiont, carbon translocation, nitrogen uptake, Symbiodinium, selfish symbiont, Physiology, QP1-981

Published

2018

2. Using Aiptasia as a Model to Study Metabolic Interactions in Cnidarian-Symbiodinium Symbioses

Author

Nils Rädecker, Jean-Baptiste Raina, Mathieu Pernice, Gabriela Perna, Paul Guagliardo, Matt R. Kilburn, Manuel Aranda, and Christian R. Voolstra

Subjects

metaorganism, holobiont, carbon translocation, nitrogen uptake, Symbiodinium, selfish symbiont, Physiology, QP1-981

Abstract

The symbiosis between cnidarian hosts and microalgae of the genus Symbiodinium provides the foundation of coral reefs in oligotrophic waters. Understanding the nutrient-exchange between these partners is key to identifying the fundamental mechanisms behind this symbiosis, yet has proven difficult given the endosymbiotic nature of this relationship. In this study, we investigated the respective contribution of host and symbiont to carbon and nitrogen assimilation in the coral model anemone Aiptaisa. For this, we combined traditional measurements with nanoscale secondary ion mass spectrometry (NanoSIMS) and stable isotope labeling to investigate patterns of nutrient uptake and translocation both at the organismal scale and at the cellular scale. Our results show that the rate of carbon and nitrogen assimilation in Aiptasia depends on the identity of the host and the symbiont. NanoSIMS analysis confirmed that both host and symbiont incorporated carbon and nitrogen into their cells, implying a rapid uptake and cycling of nutrients in this symbiotic relationship. Gross carbon fixation was highest in Aiptasia associated with their native Symbiodinium communities. However, differences in fixation rates were only reflected in the δ13C enrichment of the cnidarian host, whereas the algal symbiont showed stable enrichment levels regardless of host identity. Thereby, our results point toward a “selfish” character of the cnidarian—Symbiodinium association in which both partners directly compete for available resources. Consequently, this symbiosis may be inherently instable and highly susceptible to environmental change. While questions remain regarding the underlying cellular controls of nutrient exchange and the nature of metabolites involved, the approach outlined in this study constitutes a powerful toolset to address these questions.

Published

2018

3. Heat stress destabilizes symbiotic nutrient cycling in corals

Author

Rädecker, Nils, Pogoreutz, Claudia, Gegner, Hagen M., Cárdenas, Anny, Roth, Florian, Bougoure, Jeremy, Guagliardo, Paul, Wild, Christian, Pernice, Mathieu, Raina, Jean-Baptiste, Meibom, Anders, Voolstra, Christian R., Rädecker, Nils, Pogoreutz, Claudia, Gegner, Hagen M., Cárdenas, Anny, Roth, Florian, Bougoure, Jeremy, Guagliardo, Paul, Wild, Christian, Pernice, Mathieu, Raina, Jean-Baptiste, Meibom, Anders, and Voolstra, Christian R.

Abstract

Recurrent mass bleaching events are pushing coral reefs world-wide to the brink of ecological collapse. While the symptoms and consequences of this breakdown of the coral-algal symbiosis have been extensively characterized, our understanding of the underlying causes remains incomplete. Here, we investigated the nutrient fluxes and the physiological as well as molecular responses of the widespread coral Stylophora pistillata to heat stress prior to the onset of bleaching to identify processes involved in the break-down of the coral-algal symbiosis. We show that altered nutrient cycling during heat stress is a primary driver of the functional breakdown of the symbiosis. Heat stress increased the metabolic energy demand of the coral host, which was compensated by the catabolic degradation of amino acids. The resulting shift from net uptake to release of ammonium by the coral holobiont subsequently promoted the growth of algal symbionts and retention of photosynthates. Together, these processes form a feedback loop that will gradually lead to the decoupling of carbon translocation from the symbiont to the host. Energy limitation and altered symbiotic nutrient cycling are thus key factors in the early heat stress response, directly contributing to the breakdown of the coral-algal symbiosis. Interpreting the stability of the coral holobiont in light of its metabolic interactions provides a missing link in our understanding of the environmental drivers of bleaching and may ultimately help uncover fundamental processes underpinning the functioning of endosymbioses in general.

Published

2021

4. Corrigendum: Using Aiptasia as a Model to Study Metabolic Interactions in Cnidarian-Symbiodinium Symbioses

Author

Christian R. Voolstra, Gabriela Perna, Manuel Aranda, Mathieu Pernice, Nils Rädecker, Paul Guagliardo, Matt R. Kilburn, and Jean-Baptiste Raina

Subjects

0301 basic medicine, Physiology, Nitrogen assimilation, lcsh:Physiology, carbon translocation, 03 medical and health sciences, Symbiodinium, Symbiosis, Physiology (medical), ddc:570, 14. Life underwater, selfish symbiont, Original Research, holobiont, biology, lcsh:QP1-981, Ecology, Host (biology), Carbon fixation, Correction, Anemone, biology.organism_classification, metaorganism, holobiont, carbon translocation, nitrogen uptake, Symbiodinium, selfish symbiont, nitrogen uptake, Holobiont, 030104 developmental biology, metaorganism, Aiptasia

Abstract

© 2018 Rädecker, Raina, Pernice, Perna, Guagliardo, Kilburn, Aranda and Voolstra. The symbiosis between cnidarian hosts and microalgae of the genus Symbiodinium provides the foundation of coral reefs in oligotrophic waters. Understanding the nutrient-exchange between these partners is key to identifying the fundamental mechanisms behind this symbiosis, yet has proven difficult given the endosymbiotic nature of this relationship. In this study, we investigated the respective contribution of host and symbiont to carbon and nitrogen assimilation in the coral model anemone Aiptaisa. For this, we combined traditional measurements with nanoscale secondary ion mass spectrometry (NanoSIMS) and stable isotope labeling to investigate patterns of nutrient uptake and translocation both at the organismal scale and at the cellular scale. Our results show that the rate of carbon and nitrogen assimilation in Aiptasia depends on the identity of the host and the symbiont. NanoSIMS analysis confirmed that both host and symbiont incorporated carbon and nitrogen into their cells, implying a rapid uptake and cycling of nutrients in this symbiotic relationship. Gross carbon fixation was highest in Aiptasia associated with their native Symbiodinium communities. However, differences in fixation rates were only reflected in the δ13C enrichment of the cnidarian host, whereas the algal symbiont showed stable enrichment levels regardless of host identity. Thereby, our results point toward a "selfish" character of the cnidarian-Symbiodinium association in which both partners directly compete for available resources. Consequently, this symbiosis may be inherently instable and highly susceptible to environmental change. While questions remain regarding the underlying cellular controls of nutrient exchange and the nature of metabolites involved, the approach outlined in this study constitutes a powerful toolset to address these questions.

Published

2018

5. Heat stress destabilizes symbiotic nutrient cycling in corals.

Author

Rädecker N, Pogoreutz C, Gegner HM, Cárdenas A, Roth F, Bougoure J, Guagliardo P, Wild C, Pernice M, Raina JB, Meibom A, and Voolstra CR

Subjects

Amino Acids metabolism, Ammonium Compounds metabolism, Animals, Anthozoa genetics, Carbon metabolism, Gene Expression Regulation, Models, Biological, Nitrogen metabolism, Oxidative Stress, Photosynthesis, Anthozoa physiology, Heat-Shock Response physiology, Nutrients, Symbiosis physiology

Abstract

Recurrent mass bleaching events are pushing coral reefs worldwide to the brink of ecological collapse. While the symptoms and consequences of this breakdown of the coral-algal symbiosis have been extensively characterized, our understanding of the underlying causes remains incomplete. Here, we investigated the nutrient fluxes and the physiological as well as molecular responses of the widespread coral Stylophora pistillata to heat stress prior to the onset of bleaching to identify processes involved in the breakdown of the coral-algal symbiosis. We show that altered nutrient cycling during heat stress is a primary driver of the functional breakdown of the symbiosis. Heat stress increased the metabolic energy demand of the coral host, which was compensated by the catabolic degradation of amino acids. The resulting shift from net uptake to release of ammonium by the coral holobiont subsequently promoted the growth of algal symbionts and retention of photosynthates. Together, these processes form a feedback loop that will gradually lead to the decoupling of carbon translocation from the symbiont to the host. Energy limitation and altered symbiotic nutrient cycling are thus key factors in the early heat stress response, directly contributing to the breakdown of the coral-algal symbiosis. Interpreting the stability of the coral holobiont in light of its metabolic interactions provides a missing link in our understanding of the environmental drivers of bleaching and may ultimately help uncover fundamental processes underpinning the functioning of endosymbioses in general., Competing Interests: The authors declare no competing interest., (Copyright © 2021 the Author(s). Published by PNAS.)

Published

2021